Lyapunov exponents for the one-dimensional parabolic Anderson model with drift

Abstract

We consider the solution u to the one-dimensional parabolic Anderson model with homogeneous initial condition u(0, ·) 1, arbitrary drift and a time-independent potential bounded from above. Under ergodicity and independence conditions we derive representations for both the quenched Lyapunov exponent and, more importantly, the p-th annealed Lyapunov exponents for all p ∈ (0, ∞). These results enable us to prove the heuristically plausible fact that the p-th annealed Lyapunov exponent converges to the quenched Lyapunov exponent as p 0. Furthermore, we show that u is p-intermittent for p large enough. As a byproduct, we compute the optimal quenched speed of the random walk appearing in the Feynman-Kac representation of u under the corresponding Gibbs measure. In this context, depending on the negativity of the potential, a phase transition from zero speed to positive speed appears.