Fully nonlinear equations in conformal geometry

Speaker: 

Jeff Viaclosky

Institution: 

MIT

Time: 

Friday, January 6, 2006 - 2:00pm

Location: 

MSTB 254

I will discuss local Holder and W^{1,p} estimates for solutions of some fully nonlinear equations in conformal geometry, and analyze the behavior of singular solutions in punctured balls. I will then show how these estimates are used in the solution of the \sigma_k-Yamabe problem for k > n/2

"Analytic questions in the theory of elliptic curves"

Speaker: 

Alina Cojocaru

Institution: 

Princeton

Time: 

Friday, January 6, 2006 - 4:00pm

Location: 

MSTB 254

Many remarkable classical questions about prime numbers have natural analogues in the context of elliptic curves. In this talk I will give a brief introduction to the theory of elliptic curves, and discuss how "higher dimensional" analogues of open questions about prime numbers appear naturally in the study of the reductions of an elliptic curve. In particular, I will discuss progress made towards the resolution of variations of a Lang-Trotter conjecture from 1976.

Derivation of the cubic nonliniear Schroedinger equation from many-body quantum dynamics

Speaker: 

Benjamin Schlein

Institution: 

Harvard University

Time: 

Tuesday, January 10, 2006 - 4:00pm

Location: 

MSTB 254

We consider a system of N bosons, interacting through a repulsive short range mean field potential. In the limit of large N, we prove rigorously that the macroscopic dynamics of the system can be described in terms of the one-particle nonlinear Schroedinger equation.

Reaction and Diffusion in the Presence of Fluid Flow

Speaker: 

Andrej Zlatos

Institution: 

Univ. of Wisconsin - Madison

Time: 

Monday, January 9, 2006 - 4:00pm

Location: 

MSTB 254

In this talk I will review some recent developments in the area of reaction-diffusion-advection equations. I will concentrate on the phenomenon of quenching (extinction) of flames by a strong flow. These questions naturally lead to the related problem of estimating the relaxation speed for the solution of a corresponding passive scalar equation, which will also be discussed.

Discrete Eigenvalues and Embedded Singular Spectra

Speaker: 

David Damanik

Institution: 

Caltech

Time: 

Wednesday, January 11, 2006 - 4:00pm

Location: 

MSTB 254

We discuss a recently discovered connection between the discrete spectrum and the essential spectrum of Schr"odinger operators in one or two space dimensions. The situation is particularly interesting on the half-line since new phenomena occur in this case due to boundary effects. For example, we show that the existence of singular spectrum embedded in the essential spectrum implies that the discrete spectrum is infinite. The proof starts out by relating the problem at hand to the theory of orthogonal polynomials on the unit circle via the Szeg"o and Geronimus transformation. This transformation yields estimates on the potential, which can then be fed into an analysis of the non-linear Fourier transform arising in the Pr"ufer reformulation of the time-independent Schr"odinger equation.

Analysis of some interface and free boundary problems in continuum mechanics.

Speaker: 

Daniel Coutland

Institution: 

UC Davis

Time: 

Thursday, January 12, 2006 - 4:00pm

Location: 

MSTB 254

The main focus of my talk shall be on the well-posedness for the interface problem between a viscous fluid and an elastic solid. This is a two-phases problem, where each phase satisfies its own natural equation of evolution, and where the interaction between the two phases comes from the natural continuity of velocity field and normal stress across the unknown moving
interface. The methods known in fluid moving boundary problems (viscous or inviscid) cannot handle the apparent incompatibility between the regularity of the two phases, which has led previous authors to consider the case where the solid satisfies a simplified law where the difficulties are not present. I shall present the new methods that where required in order to allow the treatment of classical elasticity laws in this moving
interface problem.

I shall then briefly explain how some of these ideas and some new tools preserving the transport structure of the Euler equations can provide the well-posedness for the free surface Euler equations with (or without) surface tension, without any restriction on the curl of the initial velocity.

Stability of ideal plane flows

Speaker: 

Zhiwu Lin

Institution: 

Courant Institute of New York University

Time: 

Friday, January 13, 2006 - 2:00pm

Location: 

MSTB 254

Ideal plane flows are incompressible inviscid two dimensional fluids, described mathematically by the Euler equations. Infinitely many steady states exist. The stability of these steady states is a very classical problem initiated by Rayleigh in 1880. It is also physically very important since instability is believed to cause the onset of turbulence of a fluid. Nevertheless, progress in its understanding has been very slow. I will discuss several concepts of stability and some linear stability and instability criteria. In some cases nonlinear stability and instability can be showed to follow from linear results. I will also describe some methods and techniques developed recently for stability problems, one of which is to use the geometrical properties of the dynamical system for the particle trajectories.

A weak L1 bound for resolvents and the analysis of waves in random media.

Speaker: 

Jeffrey Shenker

Institution: 

Institute for Advanced Study

Time: 

Thursday, January 12, 2006 - 2:00pm

Location: 

MSTB 254

The celebrated weak L1 bound on the Hilbert transform of an L1 function provides a useful tool in the analysis of wave propagation in random media. In this talk, the application of this bound to control singularities due to rare configurations of local disorder will be discussed along with the associated "moment method" to derive Anderson localization for random Schroedinger operators.

Classical ensembles of random matrices: Gaussian, Wishart, MANOVA. From the threefold way to a \beta future

Speaker: 

Ioana Dimitriu

Institution: 

UC Berkeley

Time: 

Tuesday, January 10, 2006 - 2:00pm

Location: 

MSTB 254

In classical probability, the Gaussian, Chi-square, and Beta are three of the most studied distributions, with wide applicability. In the last century, matrix equivalents to these three distributions have emerged from nuclear physics (Gaussian ensembles) and multivariate statistics (Wishart and MANOVA ensembles). Their eigenvalue statistics have been studied in depth for three values of a parameter (\beta = 1,2,4) which defines the "threefold way" and can be thought of as a counting tool for their real, complex, or quaternion entries.

The re-examination of the Selberg integral formula, in the late '80s, has brought the advent of general \beta-ensembles, which subsume the classical cases, and for which the Boltzmann parameter \beta acts as an inverse temperature. Their eigenvalue statistics interpolate between the isolated instances 1,2, and 4, offering a "behind the scenes" perspective.

With the discovery of matrix models for the general \beta-ensembles in the early 00's, we have entered a new stage in the understanding of the complex phenomena that lie beneath the threefold way. While the \beta = 1,2,4 cases are and will always be special, we believe that the future of the classical ensembles is written in terms of a continuous \beta>0 parameter.

String Theory and Algebraic Topology

Speaker: 

Professor Ralph Cohen

Institution: 

Stanford University

Time: 

Tuesday, January 24, 2006 - 4:00pm

Location: 

MSTB 254

In this lecture I will give an overview of string topology. This is a theory that studies the
differential and algebraic topology of spaces of paths and loops in manifolds. I will describe the
algebraic topological structure of this theory, as well as its motivation from physics.
I will then discuss some applications.

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