PDE Geometric Analysis seminar: Difference between revisions

From DEV UW-Math Wiki
Jump to navigation Jump to search
No edit summary
No edit summary
Line 27: Line 27:
|[http://www.math.wisc.edu/~kchoi/ Kyudong Choi (UW Madison)]
|[http://www.math.wisc.edu/~kchoi/ Kyudong Choi (UW Madison)]
|[[#Kyudong Choi (UW Madison)|
|[[#Kyudong Choi (UW Madison)|
TBA]]
Estimates on fractional higher derivatives of weak solutions for the Navier-Stokes equations]]
|local
|local
|-
|-
Line 60: Line 60:


In linear nonautonomous second-order parabolic equations, the exponential separation refers to the exponential decay of any sign-changing solution relative to any positive solution. In this lecture, after summarizing key results on  exponential separation, we show how it can be effectively used in studies of some nonlinear parabolic problems.
In linear nonautonomous second-order parabolic equations, the exponential separation refers to the exponential decay of any sign-changing solution relative to any positive solution. In this lecture, after summarizing key results on  exponential separation, we show how it can be effectively used in studies of some nonlinear parabolic problems.
===Kyudong Choi (UW Madison)===
''Estimates on fractional higher derivatives of weak solutions for the Navier-Stokes equations''
We study weak solutions of the 3D Navier-Stokes equations with L^2 initial data. We
prove that k-th derivative of weak solutions is locally integrable in space-time for any
real k such that 1 < k < 3. Up to now, only the second derivative was known to be locally
integrable by standard parabolic regularization. We also present sharp estimates of those
quantities in weak-L^{4/(k+1)} locally. These estimates depend only on the L^2 norm of
the initial data and on the domain of integration. Moreover, they are valid even for k >=
3 as long as we have a smooth solution. The proof uses a standard approximation of
Navier-Stokes from Leray and a blow-up techniques. The local study is based on De Giorgi
techniques with a new pressure decomposition. To handle the non-locality of fractional
Laplacians, Hardy space and Maximal functions are introduced. This is joint work with A.
Vasseur.


===Yao Yao (UW Madison)===
===Yao Yao (UW Madison)===

Revision as of 16:59, 30 October 2012

The seminar will be held in room B115 of Van Vleck Hall on Mondays from 3:30pm - 4:30pm, unless indicated otherwise.

Previous PDE/GA seminars

Seminar Schedule Fall 2012

date speaker title host(s)
September 17 Bing Wang (UW Madison)
On the regularity of limit space
local
October 15 Peter Polacik (University of Minnesota)
Exponential separation between positive and sign-changing solutions and its applications
Zlatos
November 12 Kyudong Choi (UW Madison)

Estimates on fractional higher derivatives of weak solutions for the Navier-Stokes equations

local
November 19 Yao Yao (UW Madison)
Confinement for nonlocal interaction equation with repulsive-attractive kernels
local

Abstracts

Bing Wang (UW Madison)

On the regularity of limit space

This is a joint work with Gang Tian. In this talk, we will discuss how to improve regularity of the limit space by Ricci flow. We study the structure of the limit space of a sequence of almost Einstein manifolds, which are generalizations of Einstein manifolds. Roughly speaking, such manifolds are the initial manifolds of some normalized Ricci flows whose scalar curvatures are almost constants over space-time in the L1-sense, Ricci curvatures are bounded from below at the initial time. Under the non-collapsed condition, we show that the limit space of a sequence of almost Einstein manifolds has most properties which is known for the limit space of Einstein manifolds. As applications, we can apply our structure results to study the properties of K¨ahler manifolds.


Peter Polacik (University of Minnesota)

Exponential separation between positive and sign-changing solutions and its applications

In linear nonautonomous second-order parabolic equations, the exponential separation refers to the exponential decay of any sign-changing solution relative to any positive solution. In this lecture, after summarizing key results on exponential separation, we show how it can be effectively used in studies of some nonlinear parabolic problems.

Kyudong Choi (UW Madison)

Estimates on fractional higher derivatives of weak solutions for the Navier-Stokes equations

We study weak solutions of the 3D Navier-Stokes equations with L^2 initial data. We prove that k-th derivative of weak solutions is locally integrable in space-time for any real k such that 1 < k < 3. Up to now, only the second derivative was known to be locally integrable by standard parabolic regularization. We also present sharp estimates of those quantities in weak-L^{4/(k+1)} locally. These estimates depend only on the L^2 norm of the initial data and on the domain of integration. Moreover, they are valid even for k >= 3 as long as we have a smooth solution. The proof uses a standard approximation of Navier-Stokes from Leray and a blow-up techniques. The local study is based on De Giorgi techniques with a new pressure decomposition. To handle the non-locality of fractional Laplacians, Hardy space and Maximal functions are introduced. This is joint work with A. Vasseur.

Yao Yao (UW Madison)

Confinement for nonlocal interaction equation with repulsive-attractive kernels

In this talk, we consider sets of particles interacting pairwise via a potential W, which is repulsive at short distances, but attractive at long distances. The main question we consider is whether an initially compactly supported configuration remains compactly supported for all times, regardless of the number of particles. We improved the sufficient conditions on the potential W for the above confinement property to hold. This is a joint work with Jose Carrillo and Daniel Balague.