Applied/GPS: Difference between revisions
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and general Lorentz spaces. In my view, there is no relationship between this and applied | and general Lorentz spaces. In my view, there is no relationship between this and applied | ||
math. | math. | ||
===Monday, April 9: Lei Li=== | |||
''Landau-Zerner formula'' | |||
Landau-Zerner formula describes the transition rate for a 2-level quantum mechanical system. It has many applications in various models. In BO approximation, it's the basis for the surface-hopping algorithm. I'll briefly talk about how to derive this formula following the original idea of Zener proposed in 1930s. | |||
== Archived semesters == | == Archived semesters == | ||
*[[Applied/GPS/Fall2011|Fall 2011]] | *[[Applied/GPS/Fall2011|Fall 2011]] |
Revision as of 03:52, 9 April 2012
GPS Applied Mathematics Seminar
The GPS (Graduate Participation Seminar) is a weekly seminar by and for graduate students. If you're interested in presenting a topic or your own research, contact the organizers: Sarah Tumasz, Li Wang, and Zhennan Zhou.
All seminars are on Mondays from 2:25 to 3:15 in B235 Van Vleck. Speakers should aim for their talk to last no longer than 45 minutes.
Spring 2012
date | speaker | title |
---|---|---|
Feb 6 | Zhan Wang | Hydroelastic solitary wave and its application in ice problem |
Feb 13 | Sarah Tumasz | What is Topological Mixing? |
Feb 20 | Zhennan Zhou | Semi-classical analysis of Schrodinger equation with periodic potential |
Feb 27 | Li Wang | A Jin-Xin-Glimm scheme for hyperbolic conservation laws |
Mar 5 | ||
Mar 12 | ||
Mar 19 | Xiaoqian Xu | Interpolation of Linear Operators |
Mar 26 | Yu Sun | Matching-pursuit/split-operator-Fourier-transform simulations of quantum dynamics |
Apr 2 | Lei Li | Landau–Zener formula |
Apr 9 | ||
Apr 16 | ||
Apr 23 | ||
Apr 30 | ||
May 7 |
Abstracts
Monday, February 6: Zhan Wang
Hydroelastic solitary wave and its application in ice problem
The study of deformation of a floating ice sheet has applications in polar regions where ice cover is used for roads or runways and there is an interesting on the safe use of these transport links. We use the full potential model to study the forced and unforced dynamics of hydroelastic waves near the minimum phase speed in deep water. This is a joint work with Paul Milewski and J.-M. Vanden-Broeck.
Monday, February 13: Sarah Tumasz
What is Topological Mixing?
In this talk, I hope to provide an answer to the question 'What is Topological Mixing?' This will be a very introductory level talk, and I'll attempt to give intuitive, rather than technical, definitions. I'll discuss the basics of mixing, topology, and braids (as they apply) and then give some examples of applications.
Monday, February 20: Zhennan Zhou
Semi-classical analysis of Schrodinger equation with periodic potential
abstract In this talk, I plan to (at least try to) convince you that for Schrodinger equations, we need more analytic insight to build up reliable numerical schemes. I will introduce basic asymptotic methods for semiclassical limits, and explain why the situation changes dramatically for highly oscillatory potentials.
Monday, February 27: Li Wang
A Jin-Xin-Glimm scheme for hyperbolic conservation laws
We present a class of numerical scheme(called Jin-Xin-Glimm scheme) for scalar conservation law, which will be extended to hyperbolic system later. This scheme contains the advantages of Jin-Xin relaxation scheme, which is free of Riemann solver, and Glimm scheme, which is a sharp shock capturing method. This is a joint work with Frederic Coquel, Shi Jin and Jian-guo Liu.
Monday, March 19: Xiaoqian Xu
Interpolation of Linear Operators
I'll try to introduce the definition of linear operators of strong type(p,q), weak type(p,q) and restricted weak type (p,q). I'll also give the definition of weak Lp spaces and general Lorentz spaces. In my view, there is no relationship between this and applied math.
Monday, April 9: Lei Li
Landau-Zerner formula
Landau-Zerner formula describes the transition rate for a 2-level quantum mechanical system. It has many applications in various models. In BO approximation, it's the basis for the surface-hopping algorithm. I'll briefly talk about how to derive this formula following the original idea of Zener proposed in 1930s.