Components, large and small, are as they should be I: supercritical percolation on regular graphs of growing degree

Abstract

We provide sufficient conditions for a regular graph G of growing degree d, guaranteeing a phase transition in its random subgraph Gp similar to that of G(n,p) when p· d≈ 1. These conditions capture several well-studied graphs, such as (percolation on) the complete graph Kn, the binary hypercube Qd, d-regular expanders, and random d-regular graphs. In particular, this serves as a unified proof for these (and other) cases. Suppose that G is a d-regular graph on n vertices, with d=ω(1). Let ε>0 be a small constant, and let p=1+εd. Let y(ε) be the survival probability of a Galton-Watson tree with offspring distribution Po(1+ε). We show that if G satisfies a (very) mild edge expansion requirement, and if one has fairly good control on the expansion of small sets in G, then typically the percolated random subgraph Gp contains a unique giant component of asymptotic order y(ε)n, and all the other components in Gp are of order O( n/ε2). We also show that this result is tight, in the sense that if one asks for a slightly weaker control on the expansion of small sets in G, then there are d-regular graphs G on n vertices, where typically the second largest component is of order (d (n/d))=ω( n). This is the first of a two-part sequence of papers. In the subsequent work, we consider supercritical percolation on regular graphs of constant degree, and establish similar sufficient (and essentially tight) conditions in that setting.