The critical activation density in graph bootstrap percolation

Abstract

In graph bootstrap percolation, edges of an Erdős-Rényi random graph Gn,p are initially active. Activation spreads to other edges of the complete graph Kn by an iterative process governed by a fixed graph H, whereby an edge becomes active whenever it is the only inactive edge in a copy of H. If all edges of Kn are eventually activated, we say the process H-percolates. The case H=K3 corresponds to the classical sharp threshold for connectivity in Gn,p. When H=K4, there are close connections with 2-neighbor bootstrap percolation from statistical physics. Varying H produces a wide range of behaviors. In this work, for every graph H, we locate the critical H-percolation threshold pc(n,H), answering a question of Balogh, Bollobás, and Morris. Our general methods recover and improve several previous results. The location of pc(n,H) is related to a critical limiting density ρ(H) of graphs that most efficiently activate a given edge. Introducing the parameter ρ(H) raises several questions. For instance, it remains open whether ρ(H) is computable in general, and its expression appears to indicate when the H-percolation threshold is sharp.