Seminars and Colloquia by Series

Non-uniqueness and vanishing viscosity

Series
PDE Seminar
Time
Tuesday, April 8, 2025 - 15:30 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Dallas AlbrittonUniversity of Wisconsin-Madison

The forced 2D Euler equations exhibit non-unique solutions with vorticity in $L^p$, $p > 1$, whereas the corresponding Navier-Stokes solutions are unique. We investigate whether the inviscid limit $\nu \to 0^+$ from the forced 2D Navier-Stokes to Euler equations is a selection principle capable of ``resolving" the non-uniqueness. We focus on solutions in a neighborhood of the non-uniqueness scenario discovered by Vishik; specifically, we incorporate viscosity $\nu$ and consider $O(\varepsilon)$-size perturbations of his initial datum. We discover a uniqueness threshold $\varepsilon \sim \nu^{\kappa_{\rm c}}$, below which the vanishing viscosity solution is unique and radial, and at which certain vanishing viscosity solutions converge to non-unique, non-radial solutions. Joint work with Maria Colombo and Giulia Mescolini (EPFL).

Two-component L-space links, satellite and the tau-invariant

Series
Geometry Topology Seminar
Time
Monday, April 7, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 006
Speaker
Daren ChenCalTech

A result by Ozsvath and Szabo states that the knot Floer complex of an L-space knot is a staircase. In this talk, we will discuss a similar result for two-component L-space links: the link Floer complex of such links can be thought of as an array of staircases. We will describe an algorithm to extract this array directly from the H-function of the link. As an application, we will discuss how to use this and the link surgery formula to compute the knot Floer complex and the tau-invariant of a certain class of satellite knots. This is joint work with Ian Zemke and Hugo Zhou.

An energy-stable machine-learning model of non-Newtonian hydrodynamics with molecular fidelity

Series
Applied and Computational Mathematics Seminar
Time
Monday, April 7, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005 and https://gatech.zoom.us/j/94954654170
Speaker
Huan LeiMichigan State University

One essential challenge in the computational modeling of multiscale systems is the availability of reliable and interpretable closures that faithfully encode the micro-dynamics. For systems without clear scale separation, there generally exists no such a simple set of macro-scale field variables that allow us to project and predict the dynamics in a self-determined way. We introduce a machine-learning (ML) based approach that enables us to reduce high-dimensional multi-scale systems to reliable macro-scale models with low-dimensional variational structures that preserve canonical degeneracies and symmetry constraints. The non-Newtonian hydrodynamics of polymeric fluids is used as an example to illustrate the essential idea. Unlike our conventional wisdom about ML modeling that focuses on learning the PDE form, the present approach directly learns the energy variational structure from the micro-model through an end-to-end process via the joint learning of a set of micro-macro encoder functions. The final model, named the deep non-Newtonian model (DeePN2), retains a multi-scale nature with clear physical interpretation and strictly preserves the frame-indifference constraints. We show that DeePN2 can capture the broadly overlooked viscoelastic differences arising from the specific molecular structural mechanics without human intervention.

Applications of immersed curves to the study of (1,1)-satellites

Series
Dissertation Defense
Time
Friday, April 4, 2025 - 09:00 for 1 hour (actually 50 minutes)
Location
Skiles 270
Speaker
Weizhe ShenGeorgia Tech

This thesis adopts the immersed-curve perspective to analyze the knot Floer complexes of (1,1)-satellite knots. The main idea is to encode the chain model construction through what we call a planar (1,1)-pairing. This combinatorial and geometric object captures the interaction between the companion and the pattern via the geometry of immersed and embedded curves on a torus (or its planar lift). By working with explicitly constructed (1,1)-diagrams and their planar analogs, we derive rank inequalities for knot Floer homology and develop a geometric algorithm for computing torsion orders. The latter, based on a depth-search procedure, translates intricate algebraic operations into tangible geometric moves on planar (1,1)-pairings, further yielding results on unknotting numbers and fusion numbers.

Nodal Statistics for Graphs and Matrices

Series
Atlanta Combinatorics Colloquium
Time
Thursday, April 3, 2025 - 17:00 for 1 hour (actually 50 minutes)
Location
Bill Moore SSC Press Room A
Speaker
John UrschelMassachusetts Institute of Technology

The study of nodal statistics provides insight into the spectral properties of graphs and matrices, drawing strong parallels with classical results in analysis. In this talk, we will give an overview of the field, covering key results on nodal domains and nodal counts for graphs and their connection to known results in the continuous setting. In addition, we will discuss some recent progress towards a complete understanding of the extremal properties of the nodal statistics of a matrix.

Injective norm of random tensors and quantum states

Series
Stochastics Seminar
Time
Thursday, April 3, 2025 - 15:30 for 1 hour (actually 50 minutes)
Location
Skiles 006
Speaker
Stephane DartoisUniversité Paris-Saclay, CEA, List

In this talk, I will present the results of a collaboration with Benjamin McKenna on the injective norm of large random Gaussian tensors and uniform random quantum states, and describe some of the context underlying this work. The injective norm is a natural generalization to tensors of the operator norm of a matrix and appears in multiple fields. In quantum information, the injective norm is one important measure of genuine multipartite entanglement of quantum states, known as geometric entanglement. In our preprint, we provide a high-probability upper bound on the injective norm of real and complex Gaussian random tensors, which corresponds to a lower bound on the geometric entanglement of random quantum states, and to a bound on the ground-state energy of a particular multispecies spherical spin glass model.

Geometric representation of multi-dimensional data and its applications

Series
Dissertation Defense
Time
Thursday, April 3, 2025 - 08:00 for 1.5 hours (actually 80 minutes)
Location
Skiles 114
Speaker
Ho LawGeorgia Institute of Technology

This thesis presents several contributions to the fields of image and geometry processing. In 2D image processing, we propose a method that not only computes the relative depth of objects in bitmap format but also inpaints occluded regions using a PDE-based model and vector representation. Our approach demonstrates both qualitative and quantitative advantages over the state-of-the-art depth-aware bitmap-to-vector conversion models.

In the area of 3D point cloud processing, we introduce a method for generating a robust normal vector field that preserves first order discontinuity while being resistant to noise, supported by a degree of theoretical guarantee. This technique has potential applications in solving PDEs on point clouds, detecting sharp features, and reconstructing surfaces from incomplete and noisy data.

Additionally, we present a dedicated work on surface reconstruction from point cloud data. While many existing models can reconstruct implicit surfaces and some include denoising capabilities, a common drawback is the loss of sharp features: edges and corners are often smoothed out in the process. To address this limitation, we propose a method that not only denoises but also preserves sharp edges and corners during surface reconstruction from noisy data.

Cost Theory and Geometric Dualities

Series
Analysis Seminar
Time
Wednesday, April 2, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Shay SadovskyCourant Institute

In the classical theory of optimal transport, Legendre duality arises naturally, as seen for example in Kantorovich’s duality theorem. Extending this idea to a general cost function naturally leads to a broader notion of functional cost-duality and the associated class of c-functions.

Similarly, in the setting of sets, taking polars provides an analogous notion of duality, mapping to the class of convex sets. In this talk, I will introduce cost dualities for sets and show that they correspond precisely to all order-reversing involutions on sets. Finally, I will explore the connections between c-duality and various geometric and functional inequalities.

Generalized Olson-Zalik Conjecture

Series
Analysis Seminar
Time
Wednesday, April 2, 2025 - 14:00 for 1 hour (actually 50 minutes)
Location
Skiles 005
Speaker
Pu-Ting YuUniversity of Oregon

In 1992, Olson and Zalik conjectured that no system of translates can be a Schauder basis for L^2(R). This conjecture remains open as of the time of writing. Although some partial results regarding Olson-Zalik conjecture have been proved to be true, a characterization of subspaces of L^2(R) that do not admit a Schauder basis, or an unconditional basis is still unknown. 

In this talk, we will begin with a brief introduction to Olson-Zalik conjecture including its recent development. Then we will show that a family of modulation spaces do not admit unconditional bases formed by a system of translates. This observation led us to the following generalized Olson-Zalik conjecture ``Assume X is a separable Banach space that is continuously embedded into L^2(R). Then X does not admit a Schauder basis of translates if it is closed under Fourier transform". Finally, we close this talk by showing that if a closed subspace of L^2(R) is closed under Fourier transform, then it does not admit a Schauder basis of certain translates.

Manin's conjecture for Châtelet surfaces

Series
Athens-Atlanta Number Theory Seminar
Time
Tuesday, April 1, 2025 - 17:15 for 1 hour (actually 50 minutes)
Location
Skiles 314
Speaker
Katherine WooPrinceton University

We resolve Manin's conjecture for all Châtelet surfaces over $\mathbb{Q}$ (surfaces given by equations of the form x^2 + ay^2 = f(z)) -- we establish asymptotics for the number of rational points of increasing height. The key analytic ingredient is estimating sums of Fourier coefficients of modular forms along polynomial values.

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