The Second Moment Phenomenon for Monochromatic Subgraphs

Abstract

What is the chance that among a group of n friends, there are s friends all of whom have the same birthday? This is the celebrated birthday problem which can be formulated as the existence of a monochromatic s-clique Ks (s-matching birthdays) in the complete graph Kn, where every vertex of Kn is uniformly colored with 365 colors (corresponding to birthdays). More generally, for a general connected graph H, let T(H, Gn) be the number of monochromatic copies of H in a uniformly random coloring of the vertices of the graph Gn with cn colors. In this paper we show that T(H, Gn) converges to Pois(λ) whenever E T(H, Gn) → λ and Var T(H, Gn) → λ, that is, the asymptotic Poisson distribution of T(H, Gn) is determined just by the convergence of its mean and variance. Moreover, this condition is necessary if and only if H is a star-graph. In fact, the second-moment phenomenon is a consequence of a more general theorem about the convergence of T(H,Gn) to a finite linear combination of independent Poisson random variables. As an application, we derive the limiting distribution of T(H, Gn), when Gn G(n, p) is the Erd os-R\'enyi random graph. Multiple phase-transitions emerge as p varies from 0 to 1, depending on whether the graph H is balanced or unbalanced.