Analysis of a Stratified Kraichnan Flow

Abstract

We consider the stochastic convection-diffusion equation \[ ∂t u(t\,, x) = u(t\,, x) + V(t\,,x1)∂x2u(t\,, x), \] for t>0 and x=(x1\,,x2)∈R2, subject to θ0 being a nice initial profile. Here, the velocity field V is assumed to be centered Gaussian with covariance structure \[ Cov[V(t\,,a)\,,V(s\,,b)]= δ0(t-s)(a-b) all s,t0 and a,b∈R, \] where is a continuous and bounded positive-definite function on R. We prove a quite general existence/uniqueness/regularity theorem, together with a probabilistic representation of the solution that represents u as an expectation functional of an exogenous infinite-dimensional Brownian motion. We use that probabilistic representation in order to study the It\o/Walsh solution, when it exists, and relate it to the Stratonovich solution which is shown to exist for all >0. Our a priori estimates imply the physically-natural fact that, quite generally, the solution dissipates. In fact, very often, equation P\|x1|≤ mx2∈R |u(t\,, x)| = O(1 t) t∞ \=1 all m>0, equation and the O(1/ t) rate is shown to be unimproveable. Our probabilistic representation is malleable enough to allow us to analyze the solution in two physically-relevant regimes: As t∞ and as 0. Among other things, our analysis leads to a "macroscopic multifractal analysis" of the rate of decay in the above equation in terms of the reciprocal of the Prandtl (or Schmidt) number, valid in a number of simple though still physically-relevant cases.