Uniform exponential contraction for viscous Hamilton-Jacobi equations

Abstract

The well known phenomenon of exponential contraction for solutions to the viscous Hamilton-Jacobi equation in the space-periodic setting is based on the Markov mechanism. However, the corresponding Lyapunov exponent λ() characterizing the exponential rate of contraction depends on the viscosity . The Markov mechanism provides only a lower bound for λ() which vanishes in the limit 0. At the same time, in the inviscid case =0 one also has exponential contraction based on a completely different dynamical mechanism. This mechanism is based on hyperbolicity of action-minimizing orbits for the related Lagrangian variational problem. In this paper we consider the discrete time case (kicked forcing), and establish a uniform lower bound for λ() which is valid for all ≥ 0. The proof is based on a nontrivial interplay between the dynamical and Markov mechanisms for exponential contraction. We combine PDE methods with the ideas from the Weak KAM theory.