Renormalization of stochastic continuity equations on Riemannian manifolds

Abstract

We consider the initial-value problem for stochastic continuity equations of the form ∂t + divh [ (u(t,x) + Σi=1N ai(x) dWidt)] = 0, defined on a smooth closed Riemanian manifold M with metric h, where the Sobolev regular velocity field u is perturbed by Gaussian noise terms Wi(t) driven by smooth spatially dependent vector fields ai(x) on M. Our main result is that weak (L2) solutions are renormalized solutions, that is, if is a weak solution, then the nonlinear composition S() is a weak solution as well, for any "reasonable" function S:R. The proof consists of a systematic procedure for regularizing tensor fields on a manifold, a convenient choice of atlas to simplify technical computations linked to the Christoffel symbols, and several DiPerna-Lions type commutators C (,D) between (first/second order) geometric differential operators D and the regularization device ( is the scaling parameter). This work, which is related to the "Euclidean" result in Punshon-Smith (2017), reveals some structural effects that noise and nonlinear domains have on the dynamics of weak solutions.