http://mathv.chapman.edu/mathcs/api.php?action=feedcontributions&user=Jipsen&feedformat=atomMathCS - User contributions [en]2020-08-04T14:43:39ZUser contributionsMediaWiki 1.18.1http://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-03-12T04:11:10Z<p>Jipsen: </p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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<br />
=== Wednesday, April 29th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Sean Carroll, Caltech, Pasadena, CA''' ====<br />
''Title:'' '''TBA'''<br />
<br />
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<br />
<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
<br />
[http://math.chapman.edu/~jipsen/seminarposters/Christian_Williams_pcat_2020-02-21.pdf Slides from the talk]<br />
<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
<br />
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----<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2019]]<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-03-03T18:02:35Z<p>Jipsen: /* Thursday, April 29th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, April 29th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Sean Carroll, Caltech, Pasadena, CA''' ====<br />
''Title:'' '''TBA'''<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
<br />
[http://math.chapman.edu/~jipsen/seminarposters/Christian_Williams_pcat_2020-02-21.pdf Slides from the talk]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
<br />
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----<br />
<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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----<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2019]]<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-03-03T17:37:06Z<p>Jipsen: /* Speaker: Sean Carroll, Caltech, Pasadena, CA */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, April 29th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Sean Carroll, Caltech, Pasadena, CA''' ====<br />
''Title:'' '''TBA'''<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
<br />
[http://math.chapman.edu/~jipsen/seminarposters/Christian_Williams_pcat_2020-02-21.pdf Slides from the talk]<br />
<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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----<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
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----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2019]]<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-03-03T17:36:38Z<p>Jipsen: /* Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 29th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Sean Carroll, Caltech, Pasadena, CA''' ====<br />
''Title:'' ''''''<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
<br />
[http://math.chapman.edu/~jipsen/seminarposters/Christian_Williams_pcat_2020-02-21.pdf Slides from the talk]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
<br />
----<br />
----<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2019]]<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-24T05:31:49Z<p>Jipsen: /* Speaker: Christian Williams, University of California at Riverside */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
<br />
[http://math.chapman.edu/~jipsen/seminarposters/Christian_Williams_pcat_2020-02-21.pdf Slides from the talk]<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
<br />
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----<br />
<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
<br />
----<br />
----<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
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----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
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----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2019]]<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_Seminar_2019MPC Seminar 20192020-02-24T05:26:46Z<p>Jipsen: Created page with " == Spring 2019 == The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore S..."</p>
<hr />
<div><br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-24T05:26:28Z<p>Jipsen: </p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
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<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
<br />
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=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
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<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2019]]<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-24T05:25:13Z<p>Jipsen: /* Previous Seminar talks */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
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=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
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=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
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=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
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=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
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== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
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=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
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=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
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=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
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=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
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=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
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=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2019]]<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-18T05:13:57Z<p>Jipsen: /* Speaker: Christian Williams, University of California at Riverside */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. We thereby extend equational logic by first-order logic, and provide a natural type theory for algebraic structures.<br />
<br />
We demonstrate the idea with the theory of monoids, and derive the example predicate "prime". This and many algebraic examples are only useful when they are mapped from a theory into actual models. There is much to be done in this direction. However, the driving motivation of this work is the application to programming languages: we focus on applying the idea to a more general notion of theory with variable binding.<br />
<br />
The construction is given in the topos of presheaves on a theory T: a "predicate" is a sieve on an object t of T, which corresponds to a subfunctor of the representable T(-,t). For each type t, these predicates form a Heyting algebra, providing the constructors of intuitionistic logic. The operations of T can be lifted to act on predicates, and we construct a model Pred(T): T -->HeyAlg. The correspondence between the operations of T and those in the image of Pred(T) gives that the former are "polymorphic" with respect to the types of the latter. This process can be understood as providing the theory T with a polymorphic type system.<br />
<br />
The original motivation of this work is a logic for concurrency known as Namespace Logic. This applies to the reflective higher-order pi calculus, which is the language of the distributed computing platform RChain. We demonstrate the above framework by constructing namespace logic. This gives a glimpse into a large field of potential application.<br />
<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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----<br />
<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-12T04:31:42Z<p>Jipsen: /* Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. This extends equational logic by first-order logic, and provides a natural type theory for algebraic structures.<br />
<br />
The construction is given in the topos of presheaves on an algebraic theory T, by considering the Heyting algebra of subfunctors of the representables T(−, τ) for each type τ. These subfunctors are the predicates; they are constructed from the operations of the theory as well as the intuitionistic operations of the Heyting algebra.<br />
<br />
Crucially, this calculus extends from a theory to its models. Predicates represent not only classes of abstract operations, but are realized as concrete substructures in a model. Our guiding example constructs the predicate prime, and with this we derive the prime elements in a monoid.<br />
<br />
Because the technique used is very general, it applies to many notions of algebraic theory, including higher-order theories of programming languages. The predicate calculus provides a natural logical framework for algebraic structures and formal languages, which may prove useful in both mathematics and computer science.<br />
<br />
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=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho, University of Michigan''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-12T04:20:05Z<p>Jipsen: /* Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, noon - 1 pm in Keck 370, refreshments at 11:45 am (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams, University of California at Riverside''' ====<br />
<br />
''Title:'' '''Predicate Calculus for Algebraic Theories'''<br />
<br />
''Abstract:'' There is a notion of predicate for algebraic theories, which admits a calculus of both logical and algebraic operations. This extends equational logic by first-order logic, and provides a natural type theory for algebraic structures.<br />
<br />
The construction is given in the topos of presheaves on an algebraic theory T, by considering the Heyting algebra of subfunctors of the representables T(−, τ) for each type τ. These subfunctors are the predicates; they are constructed from the operations of the theory as well as the intuitionistic operations of the Heyting algebra.<br />
<br />
Crucially, this calculus extends from a theory to its models. Predicates represent not only classes of abstract operations, but are realized as concrete substructures in a model. Our guiding example constructs the predicate prime, and with this we derive the prime elements in a monoid.<br />
<br />
Because the technique used is very general, it applies to many notions of algebraic theory, including higher-order theories of programming languages. The predicate calculus provides a natural logical framework for algebraic structures and formal languages, which may prove useful in both mathematics and computer science.<br />
<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
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----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-12T01:54:53Z<p>Jipsen: /* Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams''' ====<br />
''&nbsp;''<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''The Quantum Cosmological Constant'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-12T01:51:45Z<p>Jipsen: /* Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams''' ====<br />
''&nbsp;''<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''Meditations on the Quantum Galaxy'''<br />
<br />
''Abstract:'' The mysteries surrounding the Cosmological Constant presides at the interface of quantum mechanics and gravity. In this seminar,<br />
I will provide a pedagogical discussion of the many faces of the cosmological constant problem and discuss some current research that<br />
paves new directions that invites us to rethink the quantum nature of vacuum energy.<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-12T01:47:56Z<p>Jipsen: </p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams''' ====<br />
''&nbsp;''<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
<br />
=== Wednesday, Feb 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Stephon Alexander, Brown University, Rhode Island''' ====<br />
''Title:'' '''Meditations on the Quantum Galaxy'''<br />
<br />
''Abstract:'' <br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-02-11T00:36:46Z<p>Jipsen: /* Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams''' ====<br />
''&nbsp;''<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
''Title:'' '''A categorical perspective on persistent and magnitude homology'''<br />
<br />
''Abstract:'' We define and explain both persistent homology and magnitude homology, and their respective roles in applications (in both pure and applied settings). We will exhibit how both arise as a "singular complex" of a metric space in essentially the same way, but for different values of a parameter.<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-01-12T12:17:19Z<p>Jipsen: </p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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<br />
=== Thursday, March 12th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Yelin Ou, University of Texas at Commerce''' ====<br />
''Title:'' '''Some study of biharmonic maps and submanifolds since 2000'''<br />
<br />
''Abstract:'' Biharmonic maps are maps between Riemannian manifolds which are critical points of the bi-energy. They are solutions of a system of 4thorder PDEs and they include harmonic maps and biharmonic functions as special cases. Biharmonic submanifolds (which include minimal submanifolds as special cases) are the images of biharmonic isometric immersions. The talk will review some problems, including classification of biharmonic submanifolds in space forms, biharmonic maps into spheres, biharmonic conformal maps, and unique continuation theorems, studied in this field and their progress since 2000. The talk also presents some recent work on equivariant biharmonic maps and the stability and index of biharmonic hypersurfaces in space forms.<br />
<br />
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<br />
=== Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams''' ====<br />
''&nbsp;''<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
''&nbsp;''<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan, Google Inc., Santa Barbara, CA''' ====<br />
''Title:'' '''Quantum supremacy using a programmable superconducting processor'''<br />
<br />
''Abstract:'' The promise of quantum computers is that certain computational tasks might be executed exponentially faster on a quantum processor than on a classical processor1. A fundamental challenge is to build a high-fidelity processor capable of running quantum algorithms in an exponentially large computational space. Here we report the use of a processor with programmable superconducting qubits to create quantum states on 53 qubits, corresponding to a computational state-space of dimension 2^53 (about 10^16). Measurements from repeated experiments sample the resulting probability distribution, which we verify using classical simulations. Our Sycamore processor takes about 200 seconds to sample one instance of a quantum circuit a million times—our benchmarks currently indicate that the equivalent task for a state-of-the-art classical supercomputer would take approximately 10,000 years. This dramatic increase in speed compared to all known classical algorithms is an experimental realization of quantum supremacy for this specific computational task, heralding a much-anticipated computing paradigm. If time permits, I will present some of our more recent measurements. <br />
<br />
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<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-01-10T09:14:01Z<p>Jipsen: </p>
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<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Spring 2020 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
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=== Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Christian Williams''' ====<br />
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=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Simon Cho''' ====<br />
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=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Pedram Roushan''' ====<br />
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== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
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=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
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=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
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=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
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=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
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=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
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==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
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=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
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==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
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=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
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==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
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=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
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==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
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=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
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==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
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=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
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==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
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=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
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==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
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== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
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=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
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==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
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=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
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==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
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=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
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==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
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=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
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==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
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=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
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==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
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=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
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==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
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=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
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==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
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=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
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== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
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* [[MathCS Seminar 2016]]<br />
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* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-01-10T09:05:32Z<p>Jipsen: /* Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
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=== Friday, Feb 21st, 2020, 3 - 4 pm in Keck 370, refreshments at 2:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Christian Williams''' ====<br />
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=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Simon Cho''' ====<br />
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=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Pedram Roushan''' ====<br />
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=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
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''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
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=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
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''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
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=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
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==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
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=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
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==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
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''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
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=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
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==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
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''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
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''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
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Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
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=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
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==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
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''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
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''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
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=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
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==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
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''Title:'' '''The past of a quantum particle'''<br />
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''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
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=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
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==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
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''Title:'' '''Massive Dual Gravity Revisited'''<br />
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''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
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In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
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=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
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==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
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''Title:'' '''On planar web geometry'''<br />
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''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
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=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
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==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
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''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
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''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
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NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
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=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
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==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
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''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
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''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
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''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
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His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
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== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
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=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
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==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
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''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
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''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
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=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
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==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
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''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
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''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
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=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
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==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
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''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
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''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
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=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
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==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
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''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
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''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
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=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
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==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
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''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
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''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
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=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
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==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
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''Title:'' '''Metric of an Evaporating Black Hole'''<br />
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''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
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=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
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==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
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''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
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''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
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=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
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==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
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TUESDAY, February 5th:<br />
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1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
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THURSDAY, February 7th:<br />
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10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
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11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
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1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
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2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
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3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
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FRIDAY, February 8th<br />
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10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
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11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
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2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
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3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
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SATURDAY, February 9th<br />
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1:00 - 5:00pm: Discussion session<br />
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== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2020-01-10T09:02:01Z<p>Jipsen: /* Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
<br />
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<br />
=== Tuesday, Jan 14th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Pedram Roushan''' ====<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-12-21T08:30:19Z<p>Jipsen: /* Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho''' ====<br />
<br />
<br />
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----<br />
<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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----<br />
<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-12-21T08:29:36Z<p>Jipsen: /* Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Wednesday, Feb 19th, 2020, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Simon Cho'''<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
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----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
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----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
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----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
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----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
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----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
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----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
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----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-12-09T22:52:34Z<p>Jipsen: </p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
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<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
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----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
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----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
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----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-12-09T22:51:40Z<p>Jipsen: /* Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Thursday, Dec 12th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Alí Guzmán Adán, Universiteit Gent, Belgium''' ====<br />
''Title:'' '''Pizzetti and Cauchy formulae for higher dimensional surfaces: a<br />
distributional approach'''<br />
<br />
''Abstract:'' In this talk, we study Pizzetti-type formulas for Stiefel<br />
manifolds and Cauchy-type formulas for the tangential Dirac operator<br />
from a distributional perspective. First, we illustrate a general<br />
distributional method for integration over manifolds in R^m defined by<br />
means of k equations. We apply this method to derive an alternative<br />
proof of the Pizzetti formulae for the real Stiefel manifolds<br />
SO(m)/SO(m-k). Besides, a distributional interpretation of invariant<br />
oriented integration is provided. In particular, we obtain a<br />
distributional Cauchy theorem for the tangential Dirac operator on an<br />
embedded (m-k)-dimensional smooth surface.<br />
<br />
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<br />
<br />
=== Wednesday, Dec 11th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Arjendu K Pattanayak, Physics and Astronomy, Carleton College, Northfield, Minnesota''' ====<br />
''Title:'' '''Quantum entanglement and tunneling oscillations in a (few) many-body nonlinear spin system'''<br />
<br />
''Abstract:'' Quantum tunnelling permits recoherence or refocusing in real or phase space after the initial quantum state has seemingly delocalized, exhibiting so-called classically forbidden dynamics. For a nonlinearly interacting many-body spin system this interim state can be an entangled state. We report on recent results from investigations into this phenomenon for initially spin coherent pure states in the paradigmatic kicked top (vale Haake) system. This has a mixed regualar and chaotic phase space in the classical limit and exhibits the entanglement tunneling described above, including coherent dynamics between phase-space stability islands; here the interim state is maximally entangled. We map the dependence on various parameters including nonlinear spin and number of spins involved (focusing mostly on the remarkable special case N=4) using a metric that attempts to quantify the quality and rate of tunnelling. The calculations of tunneling rates using eigenvalues and eigenstates of the time evolution operator as a function of initial condition compared to classical space structures demonstrates several nontrivial ways in which quantum behavior transitions to classical as the size of the system grows.<br />
<br />
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<br />
<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
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<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
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<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-11-27T19:15:05Z<p>Jipsen: /* Wednesday, Dec 4th, 2019, time TBA in Keck TBA, refreshments (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 4th, 2019, 4 - 5 pm in Keck 370, refreshments at 3:45 pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' '''The basics of Quantum Darwinism (and its relationship with non-Markovianity)'''<br />
<br />
''Abstract:'' Some aspects of physical systems described by quantum <br />
mechanics, most notably the possibility of violating a Bell inequality, <br />
suggests (to some) or unavoidably implies (to others) that certain <br />
properties of microscopic systems, like the precise values of position <br />
and momentum of a fundamental particle, do not have an objective <br />
reality. This strongly contrasts with the objectivity of properties of <br />
everyday macroscopic systems like the (rough estimate of) position and <br />
momentum of a baseball. Now, how can this objectivity of the <br />
macroscopic world emerge from a theory where, apparently, not all <br />
aspects of physical systems are objective? The notion of quantum <br />
Darwinism, put forward and popularized by Wojciech Zurek, is a path in <br />
that direction. In this talk I will discuss the main ideas behind <br />
quantum Darwinism, explore it in some simple models, and briefly discuss <br />
its relationship (or the lack of it) with the notion of non-Markovianity <br />
of quantum dynamical systems.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-11-20T22:56:30Z<p>Jipsen: /* Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Dec 4th, 2019, time TBA in Keck TBA, refreshments (same room) ===<br />
<br />
==== ''Speaker:'' '''Raphael Drumond, Universidade Federal de Minas Gerais, Brazil''' ====<br />
''Title:'' <br />
<br />
<br />
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----<br />
<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
''Title:'' '''Exploring the limits of no-backward-in-time signaling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signaling backwards in time.<br />
<br />
<br />
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----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
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----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
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----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-11-20T22:45:15Z<p>Jipsen: /* Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
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----<br />
<br />
=== Thursday, Nov 21th, 2019, 12:30 - 1:30 pm in Keck 370, refreshments from 12:15 (same room) ===<br />
<br />
==== ''Speaker:'' '''Sandu Popescu, University of Bristol, UK''' ====<br />
<br />
''Title:'' '''Exploring the limits of no-backward-in-time signalling'''<br />
<br />
''Abstract:'' One of the most routine observations that we make about our world is that we cannot signal backwards in time. So ubiquitous is this understanding that it is often taken as one of the basic laws of Nature. At first glance, this remark seems straightforward. However, as I will show, in probabilistic theories such as quantum mechanics, the consequences of such an assertion are far more involved. In fact, we will see that there is a surprising amount of liberty: some theories even allow the future to affect the past, nevertheless without signalling backwards in time.<br />
<br />
<br />
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----<br />
<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
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----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
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----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-30T03:02:11Z<p>Jipsen: /* Speaker: Jacques Pienaar, International Institute of Physics in Natal, Brazil */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' '''The new question in quantum foundations: what is causality?'''<br />
<br />
''Abstract:'' Work in quantum foundations has tended to concentrate on Bell's Theorem, <br />
but recently a particular aspect of that theorem has taken on a life of <br />
its own: the question of what "causality" means in quantum mechanics, <br />
and how to model it. This movement has been driven in large part by <br />
recent advances in causal modeling in the statistical and Artificial <br />
Intelligence communities, which have had a heavy influence on quantum <br />
causal modeling. These "classical" approaches tend to define causality <br />
as a probabilistic and action-centered concept, which fits well with <br />
modern information-theoretic treatments of quantum mechanics. However, <br />
the classical approaches also tend to emphasize notions of underlying <br />
determinism and objective mechanisms that do not sit so well in the <br />
quantum context. In this talk I will step back from most of the <br />
technical jargon and try to get to the heart of some of the conceptual <br />
issues involved in "quantizing" the concept of causality, critically <br />
reviewing some key findings, pointing out potential inconsistencies and <br />
outlining possible directions for further inquiry into this fascinating <br />
problem.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-28T23:28:24Z<p>Jipsen: /* Friday, Nov 8th, 2019, 3 - 4 pm in Keck TBA, refreshments from 2:45 (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck 171, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' ''' '''<br />
<br />
''Abstract:'' <br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-28T23:26:28Z<p>Jipsen: /* Speaker: Fredrik Dahlqvist */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck TBA, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist, University College London, UK''' ====<br />
<br />
''Title:'' '''A probabilistic approach to floating point arithmetic'''<br />
<br />
''Abstract:'' Finite-precision floating point arithmetic introduces rounding errors which are traditionally bounded using a worst-case analysis. However, worst-case analysis might be overly conservative because worst-case errors can be extremely rare events in practice. Here we develop a probabilistic model of rounding errors with which it becomes possible to quantify the likelihood that the rounding error of an algorithm lies within a given interval. <br />
<br />
Given an input distribution, the model requires the distribution of rounding errors. We show how to exactly compute this distribution for low precision arithmetic. For high precision arithmetic we derive a simple but surprisingly useful approximation. The model is then entirely compositional: given a numerical program written in a simple imperative programing language we can recursively compute the distribution of rounding errors at each step and propagate it through each program instruction. This is done by applying a formalism originaly developed by Kozen to understand the semantics of probabilistic programs, for example how probability distributions gets transformed by assignments or "if then else" statements.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' ''' '''<br />
<br />
''Abstract:'' <br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-25T22:11:04Z<p>Jipsen: /* Fall 2019 */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 370''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck TBA, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist''' ====<br />
<br />
''Title:'' ''' '''<br />
<br />
''Abstract:'' <br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' ''' '''<br />
<br />
''Abstract:'' <br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-25T22:06:10Z<p>Jipsen: /* Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, Nov 8th, 2019, 3 - 4 pm in Keck TBA, refreshments from 2:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Fredrik Dahlqvist''' ====<br />
<br />
''Title:'' ''' '''<br />
<br />
''Abstract:'' <br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, Nov 6th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Jacques Pienaar, International Institute of Physics in Natal, Brazil''' ====<br />
<br />
''Title:'' ''' '''<br />
<br />
''Abstract:'' <br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-18T00:12:36Z<p>Jipsen: /* Speaker: Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a quantum particle'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-17T23:04:07Z<p>Jipsen: /* Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University, Israel''' ====<br />
<br />
''Title:'' '''The past of a photon'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-17T23:03:26Z<p>Jipsen: /* Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University''' ====<br />
<br />
''Title:'' '''The past of a photon'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-17T23:03:02Z<p>Jipsen: /* Speaker: Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University''' ====<br />
<br />
''Title:'' '''The past of a photon'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according to the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
----<br />
----<br />
<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-17T23:01:56Z<p>Jipsen: /* Speaker: Prof. Lev Vaidman, Tel Aviv University */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Alex Maguy-Glass Chair in Physics of Complex Systems, Tel Aviv University''' ====<br />
<br />
''Title:'' '''The past of a photon'''<br />
<br />
''Abstract:'' Textbooks of quantum mechanics lack the concept of the past of quantum systems. Few years ago I proposed to define the past of a quantum particle according the trace it leaves. While in many cases this definition provides a reasonable description, for a nested Mach-Zehnder interferometer it leads to a picture seemingly contradicting common sense: the particle leaves a trace in a place through which it could not pass. I will discuss recent theoretical and experimental studies of this controversial issue.<br />
<br />
----<br />
----<br />
<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
<br />
----<br />
----<br />
<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
----<br />
----<br />
<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
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<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
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<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
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<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames<br />
<br />
11:30 - 12:30pm: '''Diego Valota''', ''University of Milan'', [http://math.chapman.edu/~jipsen/cecat/11th-Pointfree-Mathematics-Workshop/DiegoValota2019.pdf Computing Spectra via Dualities in the MTL hierarchy]<br />
<br />
2:00 - 3:00pm: '''Olim Tuyt''', ''University of Bern'', Algebraic finite model property of a modal Gödel logic<br />
<br />
3:00 - 4:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration, continued<br />
<br />
SATURDAY, February 9th<br />
<br />
1:00 - 5:00pm: Discussion session<br />
<br />
<br />
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<br />
<br />
<br />
== Previous Seminar talks ==<br />
<br />
* [[MPC Seminar 2018]]<br />
<br />
* [[MathCS Seminar 2017]]<br />
<br />
* [[MathCS Seminar 2016]]<br />
<br />
* [[MathCS Seminar 2015]]<br />
<br />
* [[MathCS Seminar 2014]]<br />
<br />
* [[MathCS Seminar 2013]]<br />
<br />
* [[MathCS Seminar 2012]]<br />
<br />
* [[MathCS Seminar 2011]]<br />
<br />
* [[MathCS Seminar 2010]]<br />
<br />
* [[MathCS Seminar 2009]]<br />
<br />
* [[MathCS Seminar 2008]]<br />
<br />
* [[MathCS Seminar 2007]]<br />
<br />
* [[MathCS Seminar 2006]]<br />
<br />
* [[MathCS Seminar 2005]]<br />
<br />
* [[MathCS Seminar 2004]]<br />
<br />
* [[MathCS Seminar 2003]]<br />
<br />
* [[MathCS Seminar 2002]]</div>Jipsenhttp://mathv.chapman.edu/mathcs/index.php/MPC_SeminarMPC Seminar2019-10-17T21:12:10Z<p>Jipsen: /* Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) */</p>
<hr />
<div>This is the homepage of the Chapman University '''Mathematics, Physics, and Computation Seminars'''<br />
([[MPC Seminar]])<br />
<br />
''Seminar Organizers:'' Roman Buniy and Peter Jipsen<br />
<br />
<br />
== Fall 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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<br />
=== Friday, October 18th, 2019, 12 - 1 pm in Keck 370, refreshments from 11:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Lev Vaidman, Tel Aviv University''' ====<br />
<br />
''Title:'' '''The past of a photon'''<br />
<br />
''Abstract:''<br />
<br />
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<br />
=== Friday, October 11th, 2019, 1 - 2 pm in Keck 370, refreshments from 12:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Thomas Curtright, University of Miami''' ====<br />
<br />
''Title:'' '''Massive Dual Gravity Revisited'''<br />
<br />
''Abstract:'' I will describe a highly speculative model of gravity as a massive,<br />
pure spin 2 field, which is "dual" to the usual description in terms of<br />
a spacetime metric tensor.<br />
<br />
In the dual description, for weak fields, the metric emerges as the<br />
field strength of an underlying fundamental field. More generally, if<br />
the gravitational field is not weak, the metric emerges as a nonlinear<br />
mixture involving the energy momentum tensor.<br />
<br />
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<br />
=== Wednesday, October 9th, 2019, 4 - 5 pm in Keck 370, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Alain Hénaut, Institut de Mathématiques de Bordeaux, Université de Bordeaux, France''' ====<br />
<br />
''Title:'' '''On planar web geometry'''<br />
<br />
''Abstract:'' Web geometry deals with foliations in general position. In the planar case and the complex setting, a $d$-web is given by the generic family of integral curves of an analytic or an algebraic differential equation $F(x,y,y')=0$ with $y'$-degree $d$. Invariants of these configurations as abelian relations (related to Abel's addition theorem), Lie symmetries or Godbillon-Vey sequences are investigated. This viewpoint enlarges the qualitative study of differential equations and their moduli. In the nonsingular case and through the singularities, Cartan-Spencer and meromorphic connections methods will be used. Basic examples will be given from different domains including classic algebraic geometry and WDVV-equations. Standard results and open problems will be mentioned. Illustration of the interplay between differential and algebraic geometry, new results will be presented. <br />
<br />
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<br />
=== Thursday, September 5th, 2019, 4 - 5 pm in Keck 171, refreshments from 3:45 (same room) ===<br />
<br />
==== ''Speaker:'' '''Nicole Yunger Halpern, Harvard-Smithsonian ITAMP (Institute for Theoretical Atomic, Molecular, and Optical Physics) Harvard University Department of Physics''' ====<br />
<br />
''Title:'' '''Entropic uncertainty relations for quantum-information scrambling'''<br />
<br />
''Abstract:'' How violently do two quantum operators disagree? Different subfields of physics feature different notions of incompatibility: (i) In quantum information theory, uncertainty relations are cast in terms of entropies. These entropic uncertainty relations constrain measurement outcomes. (ii) Condensed matter and high-energy physics feature interacting quantum many-body systems, such as spin chains. A local perturbation, such as a Pauli operator on one side of a chain, spreads through many-body entanglement. The perturbation comes to overlap, and to disagree, with probes localized on the opposite side of the system. This disagreement signals that quantum information about the perturbation has scrambled, or become hidden in highly nonlocal correlations. I will unite these two notions of quantum operator disagreement, presenting an entropic uncertainty relation for quantum-information scrambling. The entropies are of distributions over weak and strong measurements’ possible outcomes. The uncertainty bound strengthens when a spin chain scrambles in numerical simulations. Hence the subfields—quantum information, condensed matter, and high-energy physics—can agree about when quantum operations disagree. Our relation can be tested experimentally with superconducting qubits, trapped ions, and quantum dots.<br />
<br />
NYH, Bartolotta, and Pollack, Comms. Phys. 2, 92 (2019). https://www.nature.com/articles/s42005-019-0179-8<br />
<br />
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<br />
=== Monday, August 26, 2019, 7 - 8:30 pm, in Argyros Forum, Room 209 A&B, networking from 6:15 to 7pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Frederick Eberhardt, Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology''' ====<br />
<br />
''Title:'' '''Computing Causal Relations at Scale or Causality: From Aristotle through Computing to Zebrafish'''<br />
<br />
''Abstract:'' What causes what? How do we untangle the “why” behind processes that regulate the brain, the climate or the economy? If “Correlation does not imply causation" is the standard mantra in science, how can we ever discover causal relationships behind the data? Will it ever be possible for intelligent AI to make its own deductions and predictions? In recent years researchers have developed mathematical techniques that give us the power to infer the underlying “why” behind scientific data. What’s more, we’ve learned that we can discover these causes without performing experiments. Starting with a little practical example with lightbulbs that can be worked out by hand we will see how the problem scales as the number of variables increases. To compute the neural connections in a zebrafish brain, high performance computing is essential.<br />
<br />
''Bio:'' Frederick Eberhardt is Professor of Philosophy in the Division of the Humanities and Social Sciences at the California Institute of Technology. Before coming to Caltech he was Assistant Professor in the Philosophy-Neuroscience-Psychology (PNP) program and the Department of Philosophy at Washington University in St. Louis and a postdoc at the Institute of Cognitive and Brain Sciences at the University of California, Berkeley. As an undergraduate he attended the London School of Economics for a Bachelor in Philosophy & Mathematics. He received his PhD in philosophy from Carnegie Mellon University, where he also completed a Masters in Machine Learning.<br />
<br />
His research interests lie at the intersection of philosophy of science, machine learning and statistics. He is particularly interested in the development of methods for causal discovery from statistical data.<br />
<br />
<br />
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<br />
== Spring 2019 ==<br />
<br />
The seminar talks are held in '''Keck Center for Science and Engineering, KC 171''' (Center St. Orange, CA 92866, intersection of Center St. And Sycamore St.), '''usually on Wednesday at 4 pm'''.<br />
Sometimes there will be a change of time or venue and the announcement will reflect this change.<br />
<br />
See [http://www.chapman.edu/about/maps-directions/index.aspx Maps<br />
and directions], Keck Center is Building 28 on the Campus Map [https://www.chapman.edu/about/_files/maps-and-directions/current-maps/campus-map.pdf <br />
Campus map]<br />
<br />
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----<br />
<br />
=== Thursday, May 16, 2019 at 3 pm, in Keck 370, tea and cookies at 2:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Purbita Jana, The Institute of Mathematical Sciences, Chennai, India''' ====<br />
<br />
''Title:'' '''Intuitionistic topological systems and their connections with Heyting algebra and Gödel algebra'''<br />
<br />
''Abstract:'' (joint work with Antonio Di Nola and Revaz Grigolia) This talk will suggest a new approach of representation of a Heyting algebra as an I-topological system. I-topological systems will be introduced following the notion of topological system introduced by S. Vickers which is a triple (X, |=, A) consisting of a non-empty set X, a frame A and a relation between X and A satisfying logic of finite observations or geometric logic. It is well known that frame is the Lindenbaum algebra of geometric logic where as the Lindenbaum algebra of intuitionistic logic is a Heyting algebra. Hence to define I-topological systems, intuitionistic logic plays a crucial role. Moreover, we will focus on the categorical relationships between the I-topological system, Esakia space and Heyting algebra (and its particular case of Gödel algebra).<br />
<br />
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<br />
=== Tuesday, April 16, 2019 at 5 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Computational Evidence of Self-Organization'''<br />
<br />
''Abstract:'' Concepts are cognitive structures that people use to categorize objects and organize their knowledge of the world. Common examples include food and furniture, but also rock'n'roll, quantum physics, and blockchain. For individuals, concepts are the main tools of learning and inference; for groups of individuals (i.e., social systems), they are indispensable instruments of coordination and exchange. But how can the idiosyncratic knowledge of individuals in a social system converge on shared concepts, so as to allow coordination? Conventional wisdom in social science suggests that designated mediators, such as music critics, facilitate this convergence by endorsing the learning and usage of particular concepts. By contrast, I will argue that rational decisions embedded in everyday social interaction provide the necessary and sufficient conditions for concepts' convergence. No mediators are needed for the agents to develop a shared conceptual structure: as commonly occurs in complex adaptive systems, design emerges in the absence of centralized designers. Simulation results are presented that illustrate this point.<br />
<br />
<br />
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<br />
=== Thursday, April 11, 2019 at 4 pm, in Keck 370, tea and cookies at 3:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Dr. Michele Piazzai, University of Amsterdam, Netherlands''' ====<br />
<br />
''Title:'' '''The Ecology of Ideas: Empirical Evidence of Evolutionary Pressure'''<br />
<br />
''Abstract:'' Building on the notion that the collective cognition of agents engaged in social interaction constitutes a complex adaptive system, I present a theoretical framework to describe agents' shared conceptual structure as a self-replicating network of objects, ideas, and decisions. Finite cognitive resources at the agents' disposal create a competitive environment where concepts vie to be assigned to objects in categorization decisions, so as to survive in the agents' memory. This struggle for survival gives the socio-cognitive system traits characteristic of an ecology. I identify two sources of ecological interdependence among concepts, including horizontal relations between concepts located at the same level of abstraction and vertical relations between concepts located at different levels. An empirical model is developed to test whether these relations affect the selection of concepts in agents' decisions and the evolution of their shared conceptual structure. To test this model, I analyze one decade's worth of categorization decisions made by users of a crowd-sourced music encyclopedia whose objective is sorting records into genres and sub-genres.<br />
<br />
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<br />
=== Thursday, March 28, 2019 at 5 pm, in Keck 171, tea and cookies at 4:40pm (same room) ===<br />
<br />
==== ''Speaker:'' '''Prof. Giovanni Sambin, University of Padova, Italy''' ====<br />
<br />
''Title:'' '''Half way to Grothendieck's aim (embedding of pointwise topology into pointfree topology)'''<br />
<br />
''Abstract:'' For a mathematician, the most interesting motivation for a different foundation is when it offers a new perspective or even a solution to an old problem. Developing topology over a very "weak" foundation offers a precise mathematical expression and proof to the expectation, which is well present since the time of Grothendieck, of a notion of space generalising that of topological space.<br />
The well-known link between pointfree and standard topology (with points) is a categorical adjunction between topological spaces Top and locales Loc. Using a "weak" foundation to develop topology, one is compelled to preserve more information than usual, and thus replace topological spaces with "concrete spaces", and locales with "positive topologies". Contrary to a common expectation, it is precisely this "useless" information what offers a solution to Grothendieck's aim. That is, the above adjunction becomes a categorical embedding of concrete spaces into positive topologies.<br />
This embedding does not look possible without exploiting the presence of the new (intrinsically existential) notion of positivity relation.<br />
Half way because this leaves the problem open of finding a suitable notion of positivity (formal closed subsets) in the framework of arbitrary Grothendieck topologies.<br />
<br />
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<br />
=== Wednesday, March 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Dr. Matt Pusey, University of Oxford''' ====<br />
<br />
''Title:'' '''Anomalous weak values and contextuality: robustness and imaginary<br />
parts'''<br />
<br />
''Abstract:'' I will discuss extensions to my previous work linking anomalous weak<br />
values with contextuality. In particular, I will show that using<br />
transformation noncontextuality obviates the experimentally<br />
problematic requirement that the post-selection is projective. I will<br />
also discuss the status of the imaginary part of weak values. My talk<br />
will be based on joint work with Ravi Kunjwal and Matteo Lostaglio:<br />
https://arxiv.org/abs/1812.06940<br />
<br />
<br />
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----<br />
<br />
=== Wednesday, February 27, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Christos Tzounis, California State Polytechnic University, Pomona''' ====<br />
<br />
''Title:'' '''Metric of an Evaporating Black Hole'''<br />
<br />
''Abstract:'' We present an approximate time-dependent metric in ingoing Eddington-Finkelstein coordinates for an evaporating nonrotating black hole as a first-order perturbation of the Schwarzschild metric, using the linearized back reaction from a realistic approximation to the stress-energy tensor for the Hawking radiation in the Unruh quantum state.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Wednesday, February 13, 2019 at 4 pm, in Keck 171, tea and cookies at 3:45pm in Keck 370 ===<br />
<br />
==== ''Speaker:'' '''Prof. Peter Rakitzis, Institute of Electronic Structure and Laser, Heraklion, Greece''' ====<br />
<br />
''Title:'' '''Ultrahigh-Density Spin-Polarized H and D Atoms Observed via Magnetization Quantum Beats'''<br />
<br />
''Abstract:'' We measure nuclear and electron spin-polarized H and D densities of at least $10^{20}$ cm$^{−3}$ and $10^{19}$ cm$^{−3}$, i.e., at pressures of 5 bar and 0.5 bar, respectively, with ∼10-50 ns lifetimes, from the photodissociation of HBr and DI with circularly polarized UV light pulses. We observe the hyperfine quantum beating of the H and D magnetization with a pickup coil, i.e., the respective 0.7 and 3 ns periodic transfer of polarization from the electrons to the nuclei and back. These pulsed densities are ∼7 orders of magnitude higher than that produced by conventional continuous-production methods, and are sufficient for three novel applications: (a) laser-driven ion acceleration of spin-polarized electrons, protons, or deuterons, (b) the preparation of nuclear-spin-polarized molecules, and (c) the demonstration of spin-polarized D-T or D$^{-3}$He laser fusion at large laser facilities such as NIF, for which a reactivity enhancement of ∼50% is expected.<br />
<br />
<br />
----<br />
----<br />
<br />
=== Tuesday, February 5 -- Saturday, February 9, 2019 in Keck 370 ===<br />
<br />
==== '''11th Annual Chapman University CECAT Workshop on Pointfree Mathematics''' ====<br />
<br />
TUESDAY, February 5th:<br />
<br />
1:00 - 2:00pm '''M. Andrew Moshier''', ''Chapman University'', Weakening relations<br />
<br />
THURSDAY, February 7th:<br />
<br />
10:30 - 11:30am: '''Peter Jipsen''', ''Chapman University'', Involutive residuated lattices and relation algebras<br />
<br />
11:30 - 12:30pm: '''Sara Vannucci''', ''University of Salerno'', Semiring and Semimodule Issues in Residuated Lattices<br />
<br />
1:00 - 2:15pm: '''Rick Ball''', ''University of Denver'', Pointfree Integration<br />
<br />
2:15 - 3:15pm: '''Anna Laura Suarez''', ''University of Birmingham'', D-frames and frame coproducts<br />
<br />
3:30 - 4.30pm: '''Alex Kurz''', ''Chapman University'', On the duality theory of weakening relations<br />
<br />
FRIDAY, February 8th<br />
<br />
10:30 - 11:30am: '''Ales Pultr''', ''Charles University'', Strong Hausdorff properties of frames&l