Random walk in a high density dynamic random environment
Abstract
The goal of this note is to prove a law of large numbers for the empirical speed of a green particle that performs a random walk on top of a field of red particles which themselves perform independent simple random walks on , . The red particles jump at rate 1 and are in a Poisson equilibrium with density . The green particle also jumps at rate 1, but uses different transition kernels and depending on whether it sees a red particle or not. It is shown that, in the limit as , the speed of the green particle tends to the average jump under . This result is far from surprising, but it is non-trivial to prove. The proof that is given in this note is based on techniques that were developed in \cite{KeSi} to deal with spread-of-infection models. The main difficulty is that, due to particle conservation, space-time correlations in the field of red particles decay slowly. This places the problem in a class of random walks in dynamic random environments for which scaling laws are hard to obtain.
Cite
@article{arxiv.1305.0923,
title = {Random walk in a high density dynamic random environment},
author = {Frank den Hollander and Harry Kesten and Vladas Sidoravicius},
journal= {arXiv preprint arXiv:1305.0923},
year = {2013}
}
Comments
14 pages, 1 figure