Bootstrap percolation on infinite trees and non-amenable groups
Abstract
Bootstrap percolation on an arbitrary graph has a random initial configuration, where each vertex is occupied with probability p, independently of each other, and a deterministic spreading rule with a fixed parameter k: if a vacant site has at least k occupied neighbors at a certain time step, then it becomes occupied in the next step. This process is well-studied on Zd; here we investigate it on regular and general infinite trees and on non-amenable Cayley graphs. The critical probability is the infimum of those values of p for which the process achieves complete occupation with positive probability. On general trees, we find the following discontinuity: if the branching number of a tree is strictly smaller than k, then the critical probability is 1, while it is 1-1/k on the k-ary tree. A related result is that in any rooted tree T, there is a way of erasing k children of the root, together with all their descendants, and repeating this for all remaining children, and so on, such that the remaining tree T' has branching number (T') ≤ ((T)-k, 0). We also prove that on any 2k-regular non-amenable graph, the critical probability for the k-rule is strictly positive.
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