Transport-diffusion equations with irregular data and applications to stability estimates for second-order Hamilton-Jacobi PDEs

Abstract

This paper studies quantitative uniqueness properties in Lp spaces for Fokker-Planck and transport-diffusion equations under two new assumptions on their velocity field b=b(x,t). We first prove Lp-stability estimates for advection-diffusion PDEs when div(b)∈ Lrt(Lqx) with r∈[2,∞] and q∈[n/2,∞) satisfying the compatibility condition n/(2q)+1/r≤ 1. We then prove a stability result in L∞ for solutions of viscous transport equations when div(b(t)) fails to be integrable in time. We apply these properties to obtain new continuous dependence estimates for viscous Hamilton-Jacobi equations via integral methods. One of the main novelties in this latter setting is that the constants of the estimates are all explicit with respect to the data of the problem. These imply new uniqueness properties for diffusive Hamilton-Jacobi equations without relying on the theory of viscosity solutions.