Critical regularity and dissipativity for stochastic reaction-diffusion equations in Bochner spaces over spaces of continuous functions

Abstract

In this paper, we consider the stochastic reaction-diffusion equation du = (A u + f(u))dt + σ(u)dW on a smooth bounded domain O with homogeneous Dirichlet boundary conditions. We investigate the long-time behavior of solutions with a strongly dissipative drift nonlinearity and superlinear multiplicative noise in the Bochner space Lq(; C0(O)), q 2. Here A is a second-order self-adjoint elliptic operator and W is a two-sided trace-class Wiener process. The standard Galerkin method fails to yield energy estimates in Lq(; Lq(O)) via the It\o formula for q > 2, owing to the interference of projection operators when dealing with nonlinear terms; meanwhile, the classical theory of mild solutions lacks sufficient spatial regularity to apply the It\o formula directly. To overcome these difficulties, we consider mild solutions and establish a critical regularity estimate for the corresponding stopped process un(t) in W01,q(O), which rigorously justifies the use of the It\o formula in the non-Hilbert space Lq(; Lq(O)). As a result, we derive explicit moment energy estimates and quantitative dissipativity bounds, yielding global existence, uniqueness, and exponential asymptotic decay of solutions in Lq(; C0(O)). Unlike previous qualitative results in continuous function spaces, our framework provides a fully quantitative theory of global dissipativity.