Parabolic Anderson model with a finite number of moving catalysts

Abstract

We consider the parabolic Anderson model (PAM) which is given by the equation ∂ u/∂ t = u + u with u\, d× [0,∞) , where ∈ [0,∞) is the diffusion constant, is the discrete Laplacian, and \,d× [0,∞) is a space-time random environment that drives the equation. The solution of this equation describes the evolution of a "reactant" u under the influence of a "catalyst" . In the present paper we focus on the case where is a system of n independent simple random walks each with step rate 2d and starting from the origin. We study the annealed Lyapunov exponents, i.e., the exponential growth rates of the successive moments of u w.r.t.\ and show that these exponents, as a function of the diffusion constant and the rate constant , behave differently depending on the dimension d. In particular, we give a description of the intermittent behavior of the system in terms of the annealed Lyapunov exponents, depicting how the total mass of u concentrates as t∞. Our results are both a generalization and an extension of the work of G\"artner and Heydenreich 2006, where only the case n=1 was investigated.