Departmental Colloquium 2021-2022

The schedule for last year, 2020-2021, can be found here.

Spring 2022

January 25 (Tuesday), 11am - Zoom
Speaker: Jody Reimer, University of Leeds
Title: Mathematics for a changing Arctic – from polar bears to algae
Abstract: Sea ice is one of the largest and most dynamic biomes on Earth. This extreme, ephemeral environment supports organisms ranging from ice-adapted algae to charismatic polar bears. I will highlight several ways in which mathematics plays a vital role in understanding this ecosystem and anticipating future changes. For example, polar bear behavior can be understood through the lens of optimal control theory (e.g., stochastic dynamic programming). The responses of seal populations to environmental change can be modeled using matrix population models. Finally, ice algae provide the foundation for this ecosystem, and our understanding of regional algal blooms is improved by using methods from uncertainty quantification. I will discuss how my work in these areas has revealed underexplored mathematical connections between seemingly disparate mathematical approaches and propose future research questions at the interface between applied mathematics and ecological modeling.

January 20 (Thursday), 4:00pm - In person
Speaker: Rebecca Bellovin, University of Glasgow
Title: p-adic variation of Galois representations and modular forms
Abstract: Galois representations and modular forms are important objects of study in modern algebraic number theory. To study the relationship between them, it is often fruitful to study congruences between them. I will give an introduction to this theory, and I will conclude by discussing some recent results and applications.

January 13 (Thursday), 4:00pm - In person
Speaker: Alice Nadeau, Cornell University
Title: Mathematical Challenges in Modeling Exoplanet Climates
Abstract: In recent years over 4500 planets have been discovered outside of our solar system. These planets range from small rocky planets that harbor liquid water like Earth to gas giants like Jupiter as hot as 7000 degrees Fahrenheit. However, only limited data can be collected for each planet and dynamical models are needed to understand what these distant worlds might be like. Luckily, mathematicians have been modeling Earth's climate for at least 200 years and it is possible to adapt these Earth models to learn about our distant neighbors. Surprisingly, adaptations that we make to Earth models to understand exoplanet climates can help resolve long-standing debates about the Earth models themselves. In this talk I'll focus on the basic tools and intuition needed to model exoplanet climate and highlight my recent work on the likelihood of exoplanets with partial ice cover. The results of this work have the ancillary benefit of addressing the issue of the small ice cap instability for Earth. I’ll conclude with prospects for exoplanet modeling in the advent of the next generation of space telescopes.

January 13 (Thursday), 11:00am - In person
Speaker: Wenyu Pan, University of Chicago
Title: Exponential mixing of flows for geometrically finite hyperbolic manifolds with cusps
Abstract: Let \mathbb{H}^n be the hyperbolic n-space and \Gamma be a geometrically finite discrete subgroup in Isom_{+}(\mathbb{H}^n) with parabolic elements. We investigate whether the geodesic flow (resp. the frame flow) over the unit tangent bundle T^1(\Gamma\backslash \mathbb{H}^n) (resp. the frame bundle F(\Gamma\backslash \mathbb{H}^n)) mixes exponentially. This result has many applications, including spectral theory, prime geodesic theorems, orbit counting, equidistribution, etc. I will start with a survey of the past results, methods, and related problems on this topic. Along the way, I will present the joint work with Jialun Li, Pratyush Sarkar.

January 11 (Tuesday), 4:00pm - In person
Speaker: Geordie Williamson, University of Sydney
Title: Towards the combinatorial invariance conjecture
Abstract: The combinatorial invariance conjecture is a fascinating conjecture in Representation Theory. Basically it says that certain important polynomials are determined in a very non-trivial way by a directed graph. About 2 years ago, I began working on this problem with DeepMind, an AI lab based in London. (DeepMind is famous for their AlphaGo program which was the first program to defeat the best human Go players.) Our goal was to try to discover whether modern Machine Learning techniques are helpful in approaching problems in mathematics. I will outline how the Machine Learning models work, how successful they were and (by far the trickiest part) how we went about extracting new mathematics from these models. The result is a formula which sheds considerable light on the combinatorial invariance conjecture. This is joint work with the DeepMind team: Charles Blundell, Lars Buesing, Alex Davies and Petar Veličković.

January 10 (Monday), 4:00pm - In person
Speaker: Junshan Lin, Auburn University
Title: Electromagnetic Wave in Novel Materials and Devices: Mathematical Analysis and Numerical Computation
Abstract: The advance in fabrication technology allows for the manipulation of electromagnetic waves at various scales and with high efficiency by novel materials and devices. The significant applications of these materials and devices in physics and engineering have driven the need for mathematical studies to guide their experimental designs. In particular, rigorous mathematical theories need to be established for new types of wave-matter interactions and efficient computational methods need to be developed for the modeling of wave phenomena in complex media. Furthermore, the mathematical problems arising from the design of materials/devices and their realistic applications in many cases are inverse problems or optimization problems.
In this talk, I will exemplify how mathematical research contributes to these aspects by two research topics. The first topic is resonant wave scattering in nano-hole structures. I will present quantitative mathematical theories for various resonant scattering phenomena and fast numerical methods for their computational modeling. I will also introduce the mathematical framework for the application of resonances in biosensing and imaging. The second topic is on topological photonic materials. I will present mathematical theory to quantify the Dirac point and the interface mode induced from the topological index for one-dimensional photonic structures with both time-reversal and inversion symmetry. The studies for the two-dimensional photonic structures and related inverse design problems will also be discussed.

January 6 (Thursday), 4:00pm - In person
Speaker: Jingni Xiao, Rutgers University
Title: Scattering, Nonscattering, and Inverse Scattering
Abstract: Scattering studies the response of a known medium when probed with waves. In inverse scattering one seeks for information of an unknown medium from the exterior measurement of the scattered waves.
One of the interesting questions in both scattering and inverse scattering is whether the scattering response could be zero in the exterior when a medium is probed by certain waves. I plan to describe some results concerning this question in two different cases. The first is when the medium has corner(s) in its shape, for which we show that corners "almost" always scatter, with some exceptions. We also apply this result in inverse scattering. The other is when a medium has smooth boundary, in which case we prove the finiteness of nonscattering wavenumbers. This question is also related to invisibility, Schiffer's conjecture (and Pompeiu's problem), as well as free boundary problems.

January 6 (Thursday), 2:30pm - In person
Speaker: Spencer Leslie, Duke University
Title: Periods, L-values, and stabilization
Abstract: The study of period integrals of automorphic forms originates in deep questions about cohomology of locally symmetric spaces. A particularly powerful tool for studying periods is a relative trace formula, which often allows one to relate these integrals to other arithmetic objects like L-functions. In this talk, I review some of this story, discuss the modern approach to relating period integrals to L-functions, and introduce a new case of interest: unitary Friedberg-Jacquet periods. These periods are conjecturally related to central values of certain L-functions and are thus connected to deep conjectures on the cohomology of the associated locally symmetric spaces.
To prove these conjectural relationships, a promising approach is to use a relative trace formula. However, new problems (known as instability) arise in this setting that must be overcome if one is to prove this relation. I will discuss my work on a theory of endoscopy and stable relative trace formulae to overcome these problems. This gives a refinement of the relative trace formula amenable to proving this conjecture.

January 3 (Monday), 4:00pm - In person
Speaker: Michael Lindsey, Courant Institute New York University
Title: Tools for multimodal sampling
Abstract: The task of sampling from a probability distribution with known density arises almost ubiquitously in the mathematical sciences, from Bayesian inference to computational chemistry. The most generic and widely-used method for this task is Markov chain Monte Carlo (MCMC), though this method typically suffers from extremely long autocorrelation times when the target density has many modes that are separated by regions of low probability. We present several new methods for sampling that can be viewed as addressing this common problem, drawing on techniques from MCMC, graphical models, and tensor networks.



Fall 2021 - past

September 23 (Thursday), 4:00pm - Virtual
Speaker: David Constantine, Wesleyan University
Title: Geodesic flows on locally CAT(-1) spaces
Abstract: Geodesic flows on compact, negatively curved Riemannian manifolds famously have lots of extremely nice dynamical properties. To what extent do those properties hold for geodesic flows on metric spaces that are negatively curved? In this talk I'll discuss how we can consider geodesic flows on general metric spaces, and then discuss some results on the geodesic flow of a compact, locally CAT(-1) space. It turns out that the CAT(-1) condition is sufficient for us to recover many nice properties. This is joint work with Jean-Francois Lafont and Daniel Thompson.

September 30 (Thursday), 4:00pm - In person
Speaker: James Murphy, Tufts University
Title: Geometric and Statistical Approaches to Shallow and Deep Clustering
Abstract: We propose approaches to unsupervised clustering based on data-dependent distances and dictionary learning. By considering metrics derived from data-driven graphs, robustness to noise and ambient dimensionality is achieved. Connections to geometric analysis, stochastic processes, and deep learning are emphasized. The proposed algorithms enjoy theoretical performance guarantees on flexible data models and in some cases guarantees ensuring quasilinear scaling in the number of data points. Applications to image processing and bioinformatics will be shown, demonstrating state-of-the-art empirical performance. Extensions to active learning, generative modeling, and computational geometry will be discussed.

October 7 (Thursday), 4:00pm - Virtual
Speaker: Jennifer Balakrishnan, Boston University
Title: Rational points on curves and quadratic Chabauty
Abstract: Let C be a smooth projective curve defined over the rational numbers with genus at least 2. It was conjectured by Mordell in 1922 and proved by Faltings in 1983 that C has finitely many rational points. However, Faltings' proof does not give an algorithm for finding these points, and in practice, given a curve, provably finding its set of rational points can be quite difficult.
In the case when the Mordell--Weil rank of the Jacobian of C is less than the genus, the Chabauty--Coleman method can be used to find rational points, using the construction of certain p-adic line integrals. Nevertheless, the situation in higher rank is still rather mysterious. I will describe the quadratic Chabauty method (developed in joint work with N. Dogra, S. Müller, J. Tuitman, and J. Vonk), which can apply when the rank is equal to the genus. I will also highlight some examples of interest, from the time of Diophantus to the present day.

October 21 (Thursday), 4:00pm - In person
Speaker: Alan Reid, Rice University
Title: The geometry, topology and arithmetic of Bianchi orbifolds and their finite covers
Abstract: Let d be a square-free positive integer, and let Od denote the ring of integers in Q(sqrt(−d)) . Then the groups PSL(2,Od) are known as the Bianchi groups, and are a natural generalization of the modular group PSL(2,Z). The Bianchi groups are discrete subgroups of PSL(2,C), and as such act discontinuously on H3. The quotient Bianchi orbifolds, Qd = H3/PSL(2,Od)   are non-compact finite volume hyperbolic 3-orbifolds with hd (class number of Od ) cusps. These represent the totality of commensurability classes of non-compact arithmetic hyperbolic 3-orbifolds. This talk will survey some recent and not so recent work on understanding the geometry and topology of these orbifolds, their covers and connections to number theory.

October 26 (Tuesday), 4:00pm - Virtual, AWM Speaker Series
Speaker: Deanna Needell, University of California Los Angeles
Title: On the topic of topic modeling: enhancing machine learning approaches with topic features
Abstract: In this talk we touch on several problems in machine learning that can benefit from the use of topic modeling. We present topicmodeling based approaches for online prediction problems, computer vision, text generation, and others. While these problems have classical machine learning approaches that work well, we show that by incorporating contextual information via topic features, we obtain enhanced and more realistic results. These classical methods include non-negative matrix and tensor factorization, generative adversarial networks, and even traditional epidemiological SIR models for prediction. In this talk we provide a brief overview of these problems and show how topic features can be used in these settings. We include supporting theoretical and experimental evidence that showcases the broad use of our approaches.

November 11 (Thursday), 4:00pm - In person, Distinguished Lecturer Series
Speaker: Thomas Hales, University of Pittsburgh
Title: Formal Proof
Abstract: A formally verified proof is a proof that has been checked by software to be free of errors. The software is based on the foundational axioms and rules of logic of mathematics. This talk will give a survey of this field of research, including some of the recent theorems that have been formally verified (such as the Kepler conjecture about sphere packings and the Continuum Hypothesis). I will describe some recent advances in the technology aimed at bringing these tools to a larger mathematical audience.

November 18 (Thursday), 4:00pm - Virtual
Speaker: Charles Smart, Yale University
Title: Localization and unique continuation on the integer lattice
Abstract: I will discuss results on localization for the Anderson-Bernoulli model. This will include my work with Ding as well as work by Li-Zhang. Both develop new unique continuation results for the Laplacian on the integer lattice.

December 2 (Thursday), 4:00pm - In person
Speaker: Mason Porter, University of California Los Angeles
Title: Topological Data Analysis of Spatial Complex Systems
Abstract: From the venation patterns of leaves to spider webs, roads in cities, social networks, and the spread of COVID-19 infections and vaccinations, the structure of many systems is influenced significantly by space. In this talk, I'll discuss the application of topological data analysis (specifically, persistent homology) to spatial systems. I'll discuss a few examples, such as voting in presidential elections, city street networks, spatiotemporal dynamics of COVID-19 infections and vaccinations, and webs that were spun by spiders under the influence of various drugs.

December 14 (Tuesday), 4:00pm - In person
Speaker: Rachel Skipper, Ohio State University
Title: From simple groups to symmetries of surfaces
Abstract: We will take a tour through some families of groups of historic importance in geometric group theory, including self-similar groups and Thompson’s groups. We will discuss the rich, continually developing theory of these groups which act as symmetries of the Cantor space, and how they can be used to understand the variety of infinite simple groups. Finally, we will discuss how these groups are serving an important role in the newly developing field of big mapping class groups which are used to describe symmetries of surfaces.



Summer 2021 - past

July 6 (Tuesday), 4:00pm · (Online)
Speaker: Li-Cheng Tsai, Rutgers University
Title: When particle systems meet PDEs
Abstract: Interacting particle systems are models that involve many randomly evolving agents or particles. These systems are widely used in describing real-world phenomena. In this talk we will walk through three facets of interacting particle systems: the law of large numbers, random fluctuations, and large deviations (the study of rare events). Within each facet, I will explain how Partial Differential Equations (PDEs) play a role in understanding the systems.