The Power Light Cone of the Discrete Bak-Sneppen, Contact and other local processes

Abstract

We consider a class of random processes on graphs that include the discrete Bak-Sneppen (DBS) process and the several versions of the contact process (CP), with a focus on the former. These processes are parametrized by a probability 0≤ p ≤ 1 that controls a local update rule. Numerical simulations reveal a phase transition when p goes from 0 to 1. Analytically little is known about the phase transition threshold, even for one-dimensional chains. In this article we consider a power-series approach based on representing certain quantities, such as the survival probability or the expected number of steps per site to reach the steady state, as a power-series in p. We prove that the coefficients of those power series stabilize as the length n of the chain grows. This is a phenomenon that has been used in the physics community but was not yet proven. We show that for local events A,B of which the support is a distance d apart we have cor(A,B) = O(pd). The stabilization allows for the (exact) computation of coefficients for arbitrary large systems which can then be analyzed using the wide range of existing methods of power series analysis.