Local central limit theorem for triangle counts in sparse random graphs

Abstract

Let XH be the number of copies of a fixed graph H in G(n,p). In 2016, Gilmer and Kopparty conjectured that a local central limit theorem should hold for XH as long as H is connected, p n-1/m(H) and n2(1-p) 1, where m(H) denotes the m-density of H. Recently, Sah and Sawhney showed that the Gilmer--Kopparty conjecture holds for constant p. In this paper, we show that the Gilmer--Kopparty conjecture holds for triangle counts in the sparse range. More precisely, if p ∈ (4n-1/2, 1/2), then x∈ L| 12πe-x2/2-σ· P(X* = x)|=n-1/2+o(1)p1/2, where σ2 = Var(XK3), X*=(XK3-E(XK3))/σ and L is the support of X*. By combining our result with the results of R\"ollin--Ross and Gilmer--Kopparty, this establishes the Gilmer--Kopparty conjecture for triangle counts for n-1 p < c, for any constant c∈ (0,1). Our quantitative result is enough to prove that the triangle counts converge to an associated normal distribution also in the 1-distance. This is the first local central limit theorem for subgraph counts above the so-called m2-density threshold.