PDE Seminar: abstract

Abstract

On a bounded domain in $Ω \subseteq ℝ^{d}$ , consider the coupled heat equation

\frac{d}{d t} (\begin{matrix} u_{1} \\ ⋮ \\ u_{N} \end{matrix}) = (\begin{matrix} Δ u_{1} \\ ⋮ \\ Δ u_{N} \end{matrix}) + V (\begin{matrix} u_{1} \\ ⋮ \\ u_{N} \end{matrix}),

subject to Neumann boundary conditions, where $V : Ω \to ℝ^{N \times N}$ is a matrix-valued potential. While the solution to a single heat equation is well-known to converge to an equilibrium as $t \to \infty$ , the matrix potential $V$ can for instance introduce the existence of periodic solutions to the equation.

In this talk, we will discuss sufficient conditions for the solutions to the above equation to converge as $t \to \infty$ . We shall see that well-behavedness of the potential $V$ with respect to the $ℓ^{p}$ -unit ball in $ℝ^{n}$ is a crucial property, here – more precisely speaking, we need that $V$ is $p$ -dissipative.

What makes our analysis quite interesting is the fact that we need completely different methods for the cases $p = 2$ and $p \neq 2$ : in the first case, standard Hilbert space techniques can be used, while the case $p \neq 2$ requires more sophisticated methods from spectral geometry, the geometry of Banach spaces and semigroup theory.

This talk is based on joint work the Alexander Dobrick (Christian-Albrechts-Universität zu Kiel)

Coupled systems of heat equations and convergence to equilibrium

Abstract