PDE Geometric Analysis seminar: Difference between revisions

From UW-Math Wiki
Jump to navigation Jump to search
No edit summary
(140 intermediate revisions by 12 users not shown)
Line 2: Line 2:


===[[Previous PDE/GA seminars]]===
===[[Previous PDE/GA seminars]]===
===[[Fall 2016 | Tentative schedule for Fall 2017]]===
===[[Fall 2018 | Tentative schedule for Fall 2018]]===
 
 
 
== PDE GA Seminar Schedule Spring 2018 ==


= PDE GA Seminar Schedule Spring 2017 =


{| cellpadding="8"
{| cellpadding="8"
Line 11: Line 14:
!align="left" | title
!align="left" | title
!style="width:20%" align="left" | host(s)
!style="width:20%" align="left" | host(s)
|-
 
|January 23<br>Special time and location:<br> 3-3:50pm, B325 Van Vleck
|-
| Sigurd Angenent (UW)
|January 29, '''3-3:50PM,  B341 VV.'''
|[[#Sigurd Angenent | Ancient convex solutions to Mean Curvature Flow]]
| Dan Knopf (UT Austin)
|[[#Dan Knopf |  Non-K&auml;hler Ricci flow singularities that converge to K&auml;hler-Ricci solitons]]
| Angenent
|-
|February 5,  '''3-3:50PM, B341 VV.'''
| Andreas Seeger (UW)
|[[#Andreas Seeger | Singular integrals and  a problem on mixing flows ]]
| Kim & Tran
| Kim & Tran
|-  
|-  
 
|February 12
| Sam Krupa (UT-Austin)
|[[#Sam Krupa |  Proving Uniqueness of Solutions for Burgers Equation Entropic for a Single Entropy, with Eye Towards Systems Case ]]
| Lee
|-
|February 19
| Maja Taskovic (UPenn)
|[[#Maja Taskovic |  Exponential tails for the non-cutoff Boltzmann equation ]]
| Kim
|-
|February 26
|  Ashish Kumar Pandey (UIUC)
|[[#  |  Instabilities in shallow water wave models  ]]
| Kim & Lee
|-
|March 5
| Khai Nguyen (NCSU)
|[[#Khai Nguyen |  Burgers Equation with Some Nonlocal Sources ]]
| Tran
|-
|March 12
| Hongwei Gao (UCLA)
|[[#Hongwei Gao |  TBD ]]
| Tran
|-
|March 19
| Huy Nguyen (Princeton)
|[[#Huy Nguyen |  TBD ]]
| Lee
|-
|March 26
|
|[[#  |  Spring recess (Mar 24-Apr 1, 2018) ]]
|-
|-
|January 30
|April 2
| Serguei Denissov (UW)
| In-Jee Jeong (Princeton)
|[[#Serguei Denissov | Instability in 2D Euler equation of incompressible inviscid fluid]]
|[[#In-Jee Jeong | TBD ]]
| Kim & Tran
| Kim
|-
|April 9
| Jeff Calder (Minnesota)
|[[#Jeff Calder |  TBD ]]
| Tran
|-
|April 21-22 (Saturday-Sunday)
| Midwest PDE seminar
|[[#Midwest PDE seminar |  ]]
| Angenent, Feldman, Kim, Tran.
|-  
|-  
|April 25 (Wednesday)
| Hitoshi Ishii (Wasow lecture)
|[[#Hitoshi Ishii |  TBD]]
| Tran.
|}
== Abstracts ==
===Dan Knopf===


Title: Non-K&auml;hler Ricci flow singularities that converge to K&auml;hler-Ricci solitons


|-
Abstract: We describe Riemannian (non-K&auml;hler) Ricci flow solutions that develop finite-time Type-I singularities whose parabolic dilations converge to a shrinking K&auml;hler–Ricci soliton singularity model. More specifically, the singularity model for these solutions is the “blowdown soliton” discovered by Feldman, Ilmanen, and Knopf in 2003. Our results support the conjecture that the blowdown soliton is stable under Ricci flow. This work also provides the first set of rigorous examples of non-K&auml;hler solutions of Ricci flow that become asymptotically K&auml;hler, in suitable space-time neighborhoods of developing singularities, at rates that break scaling invariance. These results support the conjectured stability of the subspace of K&auml;hler metrics under Ricci flow.
|February 6
| Benoit Perthame (University of Paris VI)
|[[#| ]]
| Wasow lecture
|-  


===Andreas Seeger===


|-
Title: Singular integrals and a problem on mixing flows
|February 13
| Bing Wang (UW)
|[[#Bing Wang | ]]
| Kim & Tran
|-


|-
Abstract: The talk will be about  results related to Bressan's mixing problem. We present  an inequality for the change of a  Bianchini semi-norm of characteristic functions under the  flow generated by a divergence free time dependent vector field. The approach leads to a bilinear singular integral operator  for which one proves bounds  on Hardy spaces. This is joint work with Mahir Hadžić,  Charles Smart and    Brian Street.
|February 20
| Hans-Joachim Hein (Fordham)
|[[#Hans-Joachim Hein | ]]
| Viaclovsky
|-  


|-
===Sam Krupa===
|February 27
| Ben Seeger (University of Chicago)
|[[#Ben Seeger | ]]
| Tran
|-


|-
Title: Proving Uniqueness of Solutions for Burgers Equation Entropic for a Single Entropy, with Eye Towards Systems Case
|March 7 - Applied math/PDE/Analysis seminar
| Roger Temam (Indiana University) 
|[[#| ]]
| Mathematics Department Distinguished Lecture
|-


Abstract: For hyperbolic systems of conservation laws, uniqueness of solutions is still largely open. We aim to expand the theory of uniqueness for systems of conservation laws. One difficulty is that many systems have only one entropy. This contrasts with scalar conservation laws, where many entropies exist. It took until 1994 to show that one entropy is enough to ensure uniqueness of solutions for the scalar conservation laws (Panov). This single entropy result was proven again by De Lellis, Otto and Westdickenberg in 2004. These two proofs both rely on the special connection between Hamilton--Jacobi equations and scalar conservation laws in one space dimension. However, this special connection does not extend to systems. In our new work, we prove the single entropy result for scalar conservation laws without using Hamilton--Jacobi.  Our proof lays out new techniques that are promising for showing uniqueness of solutions in the systems case. This is joint work with A. Vasseur.


|-
|March 8 - Applied math/PDE/Analysis seminar
| Roger Temam (Indiana University) 
|[[#| ]]
| Mathematics Department Distinguished Lecture
|-


|-
===Maja Taskovic===
|March 13
| Sona Akopian (UT-Austin)
|[[#Sona Akopian | ]]
| Kim


|-
Title: Exponential tails for the non-cutoff Boltzmann equation
|March 27 - Analysis/PDE seminar
| Sylvia Serfaty (Courant)
|[[#Sylvia Serfaty | ]]
| Tran


|-
Abstract: The Boltzmann equation models the motion of a rarefied gas, in which particles interact through binary collisions, by describing the evolution of the particle density function.  The effect of collisions on the density function is modeled by a bilinear integral operator (collision operator) which in many cases has a non-integrable angular kernel.  For a long time the equation was simplified by assuming that this kernel is integrable (the so called Grad's cutoff) with a belief that such an assumption does not affect the equation significantly. However, in the last 20 years it has been observed that a non-integrable singularity carries regularizing properties which motivates further analysis of the equation in this setting.
|March 29
| Sylvia Serfaty (Courant)
|[[#Sylvia Serfaty | ]]
| Wasow lecture


|-
We study behavior in time of tails of solutions to the Boltzmann equation in the non-cutoff regime by examining the generation and propagation of $L^1$ and $L^\infty$ exponentially weighted estimates and the relation between them. For this purpose we introduce Mittag-Leffler moments which can be understood as a generalization of exponential moments. An interesting aspect of this result is that the singularity rate of the angular kernel affects the order of tails that can be shown to propagate in time. This is based on joint works with Alonso, Gamba, Pavlovic and Gamba, Pavlovic.
|April 3
| Zhenfu Wang (Maryland)
|[[#Zhenfu Wang | ]]
| Kim


|-
|April 10
| Andrei Tarfulea (Chicago)
|[[#Andrei Tarfulea | Improved estimates for thermal fluid equations]]
| Baer


|-
===Ashish Kumar Pandey===
|May 1st
| Jeffrey Streets (UC-Irvine)
|[[#Jeffrey Streets | ]]
| Bing Wang
|}


=Abstracts=
Title: Instabilities in shallow water wave models


===Sigurd Angenent===
Abstract: Slow modulations in wave characteristics of a nonlinear, periodic traveling wave in a dispersive medium may develop non-trivial structures which evolve as it propagates. This phenomenon is called modulational instability. In the context of water waves, this phenomenon was observed by Benjamin and Feir and, independently, by Whitham in Stokes' waves. I will discuss a general mechanism to study modulational instability of periodic traveling waves which can be applied to several classes of nonlinear dispersive equations including KdV, BBM, and regularized Boussinesq type equations.
The Huisken-Hamilton-Gage theorem on compact convex solutions to MCF shows that in forward time all solutions do the same thing, namely, they shrink to a point and become round as they do so. Even though MCF is ill-posed in backward time there do exist solutions that are defined for all t<0 , and one can try to classify all such &ldquo;Ancient Solutions.&rdquo;  In doing so one finds that there is interesting dynamics associated to ancient solutions. I will discuss what is currently known about these solutions.  Some of the talk is based on joint work with Sesum and Daskalopoulos.




===Serguei Denissov===
===Khai Nguyen===
We consider the patch evolution under the 2D Euler dynamics and study how the geometry of the boundary can deteriorate in time.


Title: Burgers Equation with Some Nonlocal Sources


===Andrei Tarfulea===
Abstract: Consider the Burgers equation with some nonlocal sources, which were derived from models of nonlinear wave with constant frequency. This talk  will present some recent results on the global existence of entropy weak solutions, priori estimates, and a uniqueness result for both Burgers-Poisson and Burgers-Hilbert equations.  Some open questions will be discussed.
We consider a model for three-dimensional fluid flow on the torus that also keeps track of the local temperature. The momentum equation is the same as for Navier-Stokes, however the kinematic viscosity grows as a function of the local temperature. The temperature is, in turn, fed by the local dissipation of kinetic energy. Intuitively, this leads to a mechanism whereby turbulent regions increase their local viscosity and
dissipate faster. We prove a strong a priori bound (that would fall within the Ladyzhenskaya-Prodi-Serrin criterion for ordinary Navier-Stokes) on the thermally weighted enstrophy for classical solutions to the coupled system.

Revision as of 12:31, 21 February 2018

The seminar will be held in room 901 of Van Vleck Hall on Mondays from 3:30pm - 4:30pm, unless indicated otherwise.

Previous PDE/GA seminars

Tentative schedule for Fall 2018

PDE GA Seminar Schedule Spring 2018

date speaker title host(s)
January 29, 3-3:50PM, B341 VV. Dan Knopf (UT Austin) Non-Kähler Ricci flow singularities that converge to Kähler-Ricci solitons Angenent
February 5, 3-3:50PM, B341 VV. Andreas Seeger (UW) Singular integrals and a problem on mixing flows Kim & Tran
February 12 Sam Krupa (UT-Austin) Proving Uniqueness of Solutions for Burgers Equation Entropic for a Single Entropy, with Eye Towards Systems Case Lee
February 19 Maja Taskovic (UPenn) Exponential tails for the non-cutoff Boltzmann equation Kim
February 26 Ashish Kumar Pandey (UIUC) Instabilities in shallow water wave models Kim & Lee
March 5 Khai Nguyen (NCSU) Burgers Equation with Some Nonlocal Sources Tran
March 12 Hongwei Gao (UCLA) TBD Tran
March 19 Huy Nguyen (Princeton) TBD Lee
March 26 Spring recess (Mar 24-Apr 1, 2018)
April 2 In-Jee Jeong (Princeton) TBD Kim
April 9 Jeff Calder (Minnesota) TBD Tran
April 21-22 (Saturday-Sunday) Midwest PDE seminar Angenent, Feldman, Kim, Tran.
April 25 (Wednesday) Hitoshi Ishii (Wasow lecture) TBD Tran.

Abstracts

Dan Knopf

Title: Non-Kähler Ricci flow singularities that converge to Kähler-Ricci solitons

Abstract: We describe Riemannian (non-Kähler) Ricci flow solutions that develop finite-time Type-I singularities whose parabolic dilations converge to a shrinking Kähler–Ricci soliton singularity model. More specifically, the singularity model for these solutions is the “blowdown soliton” discovered by Feldman, Ilmanen, and Knopf in 2003. Our results support the conjecture that the blowdown soliton is stable under Ricci flow. This work also provides the first set of rigorous examples of non-Kähler solutions of Ricci flow that become asymptotically Kähler, in suitable space-time neighborhoods of developing singularities, at rates that break scaling invariance. These results support the conjectured stability of the subspace of Kähler metrics under Ricci flow.

Andreas Seeger

Title: Singular integrals and a problem on mixing flows

Abstract: The talk will be about results related to Bressan's mixing problem. We present an inequality for the change of a Bianchini semi-norm of characteristic functions under the flow generated by a divergence free time dependent vector field. The approach leads to a bilinear singular integral operator for which one proves bounds on Hardy spaces. This is joint work with Mahir Hadžić, Charles Smart and Brian Street.

Sam Krupa

Title: Proving Uniqueness of Solutions for Burgers Equation Entropic for a Single Entropy, with Eye Towards Systems Case

Abstract: For hyperbolic systems of conservation laws, uniqueness of solutions is still largely open. We aim to expand the theory of uniqueness for systems of conservation laws. One difficulty is that many systems have only one entropy. This contrasts with scalar conservation laws, where many entropies exist. It took until 1994 to show that one entropy is enough to ensure uniqueness of solutions for the scalar conservation laws (Panov). This single entropy result was proven again by De Lellis, Otto and Westdickenberg in 2004. These two proofs both rely on the special connection between Hamilton--Jacobi equations and scalar conservation laws in one space dimension. However, this special connection does not extend to systems. In our new work, we prove the single entropy result for scalar conservation laws without using Hamilton--Jacobi. Our proof lays out new techniques that are promising for showing uniqueness of solutions in the systems case. This is joint work with A. Vasseur.


Maja Taskovic

Title: Exponential tails for the non-cutoff Boltzmann equation

Abstract: The Boltzmann equation models the motion of a rarefied gas, in which particles interact through binary collisions, by describing the evolution of the particle density function. The effect of collisions on the density function is modeled by a bilinear integral operator (collision operator) which in many cases has a non-integrable angular kernel. For a long time the equation was simplified by assuming that this kernel is integrable (the so called Grad's cutoff) with a belief that such an assumption does not affect the equation significantly. However, in the last 20 years it has been observed that a non-integrable singularity carries regularizing properties which motivates further analysis of the equation in this setting.

We study behavior in time of tails of solutions to the Boltzmann equation in the non-cutoff regime by examining the generation and propagation of $L^1$ and $L^\infty$ exponentially weighted estimates and the relation between them. For this purpose we introduce Mittag-Leffler moments which can be understood as a generalization of exponential moments. An interesting aspect of this result is that the singularity rate of the angular kernel affects the order of tails that can be shown to propagate in time. This is based on joint works with Alonso, Gamba, Pavlovic and Gamba, Pavlovic.


Ashish Kumar Pandey

Title: Instabilities in shallow water wave models

Abstract: Slow modulations in wave characteristics of a nonlinear, periodic traveling wave in a dispersive medium may develop non-trivial structures which evolve as it propagates. This phenomenon is called modulational instability. In the context of water waves, this phenomenon was observed by Benjamin and Feir and, independently, by Whitham in Stokes' waves. I will discuss a general mechanism to study modulational instability of periodic traveling waves which can be applied to several classes of nonlinear dispersive equations including KdV, BBM, and regularized Boussinesq type equations.


Khai Nguyen

Title: Burgers Equation with Some Nonlocal Sources

Abstract: Consider the Burgers equation with some nonlocal sources, which were derived from models of nonlinear wave with constant frequency. This talk will present some recent results on the global existence of entropy weak solutions, priori estimates, and a uniqueness result for both Burgers-Poisson and Burgers-Hilbert equations. Some open questions will be discussed.