Hydrodynamic Limit for the SSEP with a Slow Membrane

Abstract

In this paper we consider a symmetric simple exclusion process (SSEP) on the d-dimensional discrete torus TdN with a spatial non-homogeneity given by a slow membrane. The slow membrane is defined here as the boundary of a smooth simple connected region on the continuous d-dimensional torus Td. In this setting, bonds crossing the membrane have jump rate α/Nβ and all other bonds have jump rate one, where α>0, β∈[0,∞], and N∈ N is the scaling parameter. In the diffusive scaling we prove that the hydrodynamic limit presents a dynamical phase transition, that is, it depends on the regime of β. For β∈[0,1), the hydrodynamic equation is given by the usual heat equation on the continuous torus, meaning that the slow membrane has no effect in the limit. For β∈(1,∞], the hydrodynamic equation is the heat equation with Neumann boundary conditions, meaning that the slow membrane ∂ divides Td into two isolated regions and . And for the critical value β=1, the hydrodynamic equation is the heat equation with certain Robin boundary conditions related to the Fick's Law.