Mean Field Behavior during the Big Bang Regime for Coalescing Random Walks

Abstract

In this paper we consider coalescing random walks on a general connected graph G=(V,E). We set up a unified framework to study the leading order of the decay rate of Pt, the expectation of the fraction of occupied sites at time t, particularly for the `Big Bang' regime where t tcoal:=E[∈f\s:There is only one particle at time s\]. Our results show that Pt satisfies certain mean field behavior, if the graphs satisfy certain transience-like conditions. We apply this framework to two families of graphs: (1) graphs given by the configuration model with a degree distribution supported in [3, d] for some d≥ 3, and (2) finite and infinite vertex-transitive graphs. In the first case, we show that for 1 t |V|, Pt decays in the order of t-1, and (tPt)-1 is approximately the probability that two particles starting from the root of the corresponding unimodular Galton-Watson tree never collide after one of them leaves the root, which is also roughly |V|/(2tmeet), where tmeet is the mean meeting time of two walkers. By taking the local weak limit, for the unimodular Galton-Watson tree we prove the convergence of tPt as t∞. For the second family of graphs, if we take a sequence of finite graphs Gn=(Vn, En), such that tmeet=O(|Vn|) and the inverse of the spectral gap trel is o(|Vn|), then for trel t tcoal, (tPt)-1 is approximately the probability that two random walks never meet before time t, and also |V|/(2tmeet). In addition, we define a natural uniform transience condition, and show that it implies the above for all 1 t tcoal. Such estimates of tPt are also obtained for all infinite transient transitive unimodular graphs, in particular, all transient transitive amenable graphs.