The random heat equation in dimensions three and higher: the homogenization viewpoint

Abstract

We consider the stochastic heat equation ∂su =12 u +(β V(s,y)-λ)u, with a smooth space-time stationary Gaussian random field V(s,y), in dimensions d≥ 3, with an initial condition u(0,x)=u0( x) and a suitably chosen λ∈ R. It is known that, for β small enough, the diffusively rescaled solution u(t,x)=u(-2t,-1x) converges weakly to a scalar multiple of the solution u(t,x) of the heat equation with an effective diffusivity a, and that fluctuations converge, also in a weak sense, to the solution of the Edwards-Wilkinson equation with an effective noise strength and the same effective diffusivity. In this paper, we derive a pointwise approximation w(t,x)= u(t,x)(t,x)+ u1(t,x), where (t,x)=(t/2,x/), is a solution of the SHE with constant initial conditions, and u1 is an explicit corrector. We show that (t,x) converges to a stationary process (t,x) as t∞, that E|u(t,x)-w(t, x)|2 converges pointwise to 0 as 0, and that -d/2+1(u-w) converges weakly to 0 for fixed t. As a consequence, we derive new representations of the diffusivity a and effective noise strength . Our approach uses a Markov chain in the space of trajectories introduced in Gu, Ryzhik, and Zeitouni, "The Edwards-Wilkinson limit of the random heat equation in dimensions three and higher," as well as tools from homogenization theory. The corrector u1(t,x) is constructed using a seemingly new approximation scheme on a mesoscopic time scale.