On a particle approximation to the Dean-Kawasaki type equation with logarithmic interactions

Abstract

We consider a class of Dean-Kawasaki type equations on T with logarithmic repulsive interactions depending on the inverse temperature β and a new spectral approximation to the noise part, which approximately features Otto's metric in P(T). Following the idea of intrinsic constructions of Brownian motions on the Wasserstein space, we construct a class of particle models whose fluctuating hydrodynamic limits, denoted as ptβ, are solutions to the martingale problems of this class of equations. Specifically, we give a quantitative convergence rate of the particle approximation, which allows us to identify a unique limit distribution depending on β. As the inverse temperature rises, the regularizing effect of repulsive interactions becomes stronger. We prove that there exists three thresholds 0<λ0≤λ1<λ2 depending on the noise such that, when β>λ0, ptβ is a non-atomic measure process in P(T); when β>λ1, ptβ is absolutely continuous with respect to Lebesgue measure almost surely; when β>λ2, the expectation of the R\'enyi entropy of ptβ satisfies an exponential decay estimate.