Intermittence and nonlinear parabolic stochastic partial differential equations

Abstract

We consider nonlinear parabolic SPDEs of the form ∂t u= u + σ(u) w, where w denotes space-time white noise, σ: is [globally] Lipschitz continuous, and is the L2-generator of a L\'evy process. We present precise criteria for existence as well as uniqueness of solutions. More significantly, we prove that these solutions grow in time with at most a precise exponential rate. We establish also that when σ is globally Lipschitz and asymptotically sublinear, the solution to the nonlinear heat equation is ``weakly intermittent,'' provided that the symmetrization of is recurrent and the initial data is sufficiently large. Among other things, our results lead to general formulas for the upper second-moment Liapounov exponent of the parabolic Anderson model for in dimension (1+1). When =∂xx for >0, these formulas agree with the earlier results of statistical physics Kardar,KrugSpohn,LL63, and also probability theory BC,CM94 in the two exactly-solvable cases where u0=δ0 and u0 1.