On a class of doubly nonlinear evolution equations in Musielak-Orlicz spaces

Abstract

This paper is concerned with a parabolic evolution equation of the form A(ut) + B(u) = f, settled in a smooth bounded domain of Rd, d ≥ 1, and complemented with the initial conditions and with (for simplicity) homogeneous Dirichlet boundary conditions. Here, -B stands for a diffusion operator, possibly nonlinear, which may range in a very wide class, including the Laplacian, the m-Laplacian for suitable m∈(1,∞)), the "variable-exponent" m(x)-Laplacian, or even some fractional order operators. The operator A is assumed to be in the form [A(v)](x, t) = α(x, v(x, t)) with α being measurable in x and maximal monotone in v. The main results are devoted to proving existence of weak solutions for a wide class of functions α that extends the setting considered in previous results related to the variable exponent case where α(x, v) = |v(x)|p(x)-2 v(x). To this end, a theory of subdifferential operators will be established in Musielak-Orlicz spaces satisfying structure conditions of the so-called 2-type and a framework for approximating maximal monotone operators acting in that class of spaces will also be developed. Such a theory is then applied to provide an existence result for a specific equation, but it may have an independent interest in itself. Finally, the existence result is illustrated by presenting a number of specific equations (and, correspondingly, of operators A, B) to which the result can be applied.