Singular diffusion limit of a tagged particle in zero range processes with Sinai-type random environment
Abstract
We derive a singular diffusion limit for the position of a tagged particle in zero range interacting particle processes on a one dimensional torus with a Sinai-type random environment via two steps. In the first step, a regularization is introduced by averaging the random environment over an N-neighborhood. With respect to such an environment, the microscopic drift of the tagged particle is in form 1NW', where W' is a regularized White noise. Scaling diffusively, we find the nonequilibrium limit of the tagged particle xt is the unique weak solution of d xt = 2((t, xt))(t, xt) \,W'(xt) + ((t, xt))(t, xt) \,dBt, in terms of the hydrodynamic mass density recently identified and homogenized interaction rate . In the second step, we show that x, as vanishes, converges in law to the diffusion x0 described informally by d xt0 = 2(0(t, xt0))0(t, xt0) \,W'(xt0) + (0(t, xt0))0(t, xt0) \,dBt, where W' is a spatial White noise and 0 is the para-controlled limit of also recently identified, solving the singular PDE ∂t 0 = 12 (0) - 2∇ (W' (0)).
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.