Lyapunov exponents in a slow environment

Abstract

Motivated by the evolution of a population in a slowly varying random environment, we consider the 1D Anderson model on finite volume, with viscosity > 0 : ∂t u(t,x) = u(t,x) + (t, x) u(t,x), u(0, x) = u0(x), t > 0, x ∈ T. The noise is chosen constant on time intervals of length τ >0 and sampled independently after a time τ . We prove that the Lyapunov exponent λ (τ) is positive and near τ= 0 follows a power law that depends on the regularity on the driving noise. As τ ∞ the Lyapunov exponent converges to the average top eigenvalue of the associated time-independent Anderson model. The proofs make use of a solid control of the projective component of the solution and build on the Furstenberg--Khasminskii and Bou\'e--Dupuis formulas, as well as on Doob's H-transform and on tools from singular stochastic PDEs.