Numerical Approximation of Young Measure Solutions to Parabolic Systems of Forward-Backward Type

Abstract

This paper is concerned with the proof of existence and numerical approximation of large-data global-in-time Young measure solutions to initial-boundary-value problems for multidimensional nonlinear parabolic systems of forward-backward type of the form ∂t u - div(a(Du)) + Bu = F, where B ∈ Rm × m, Bv · v ≥ 0 for all v ∈ Rm, F is an m-component vector-function defined on a bounded open Lipschitz domain Ω⊂ Rn, and a is a locally Lipschitz mapping of the form a(A)=K(A)A, where K\,:\, Rm × n → R. The function a may have a nonstandard growth rate, in the sense that it is permitted to have unequal lower and upper growth rates. Furthermore, a is not assumed to be monotone, nor is it assumed to be the gradient of a potential. Problems of this type arise in mathematical models of the atmospheric boundary layer and fall beyond the scope of monotone operator theory. We develop a numerical algorithm for the approximate solution of problems in this class, and we prove the convergence of the algorithm to a Young measure solution of the system under consideration.