The parabolic Anderson model in a dynamic random environment: space-time ergodicity for the quenched Lyapunov exponent

Abstract

We continue our study of the parabolic Anderson equation ∂ u(x,t)/∂ t = u(x,t) + (x,t)u(x,t), x∈d, t≥ 0, where ∈ [0,∞) is the diffusion constant, is the discrete Laplacian, and plays the role of a dynamic random environment that drives the equation. The initial condition u(x,0)=u0(x), x∈d, is taken to be non-negative and bounded. The solution of the parabolic Anderson equation describes the evolution of a field of particles performing independent simple random walks with binary branching: particles jump at rate 2d, split into two at rate 0, and die at rate (-) 0. We assume that is stationary and ergodic under translations in space and time, is not constant and satisfies (|(0,0)|)<∞, where denotes expectation w.r.t.\ . Our main object of interest is the quenched Lyapunov exponent λ0 () = t∞ 1t u(0,t). In earlier work we showed that under certain mild space-time mixing assumptions the limit exists -a.s., is finite and continuous on [0,∞), is globally Lipschitz on (0,∞), is not Lipschitz at 0, and satisfies λ0(0) = ((0,0)) and λ0() > ((0,0)) for ∈ (0,∞).In the present paper we show that ∞ λ0() =((0,0)) under an additional space-time mixing condition on . This result shows that the parabolic Anderson model exhibits space-time ergodicity in the limit of large diffusivity. This fact is interesting because there are choices of that fulfill our assumption for which the annealed Lyapunov exponent λ1() = t∞ 1t (u(0,t)) is infinite on [0,∞), a situation that is referred to as strongly catalytic behavior.