University of Manitoba Simon Fraser University

Centre recherches mathématique

Fields Institute

Pacific Institute for the Mathematical Sciences

Institute for Quantum Computing

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CMS Jeffery-Williams Prize

NASSIF GHOUSSOUB, University of British Columbia
A Self-dual Variational Calculus and its Applications

How to solve PDEs by completing squares? Motivated in part by the basic equations of quantum field theory (e.g. Yang-Mills, Ginzburg-Landau, etc....), we identify a large class of partial differential equations that can be solved via a newly devised "self-dual" variational calculus.

In both stationary and dynamic cases, such self-dual equations are not derived from the fact they are critical points of action functionals, but because they are also zeroes of appropriately chosen non-negative Lagrangians. The class contains many of the basic families of linear and nonlinear, stationary and evolutionary partial differential equations: Transport equations, Nonlinear Laplace equations, Cauchy-Riemann systems, Navier-Stokes equations, but also infinite dimensional gradient flows of convex potentials (e.g. heat equations), nonlinear Schrödinger equations, Hamiltonian systems, and many other parabolic-elliptic equations.