Contributions to Books:
A. Arnold, A. Einav, B. Signorello, T. Wöhrer:
"Large time convergence of the non-homogeneous Goldstein-Taylor equation";
in: "ASC Report 22/2020",
issued by: Institute for Analysis and Scientific Computing;
Vienna University of Technology,
The Goldstein-Taylor equations can be thought of as a simplified
version of a BGK system,where the velocity variable is constricted to a discrete set of values. It is intimately related to turbulent fluid motion and the telegrapher´s equation. A detailed understanding of the large time behaviour of the solutions to these equations has been mostly achieved in the case where the relaxation function, measuring the intensity of the relaxation towards equally distributed velocity densities, is constant. The goal of the presented work is to provide a general method to tackle the question of convergence to equilibrium
when the relaxation function is not constant, and to do so as quantitatively as possible. In contrast to the usual modal composition of the equations, which is natural when the relaxation function is constant, we define a new Lyapunov functional of pseudodifferential nature, one that is motivated by the modal analysis in the constant case, that is able to deal with full spatial dependency of the relaxation function. The approach we develop is robust enough that one can apply it to multi-velocity Goldstein-Taylor models, and achieve explicit rates of convergence. The convergence rate we find, however,
is not optimal, as we show by comparing our result to the that found in .
BGK equation, hypocoercivity, large time behaviour, exponential decay, Lyapunov functional MSC. 82C40 (Kinetic theory of gases in time-dependent statistical mechanics), 35B40 (Asymptotic behavior of solutions to PDEs), 35Q82 (PDEs in connection with stati
Electronic version of the publication:
Created from the Publication Database of the Vienna University of Technology.