Thresholds for Latin squares and Steiner triple systems: Bounds within a logarithmic factor

Abstract

We prove that for n ∈ N and an absolute constant C, if p ≥ C2 n / n and Li,j ⊂eq [n] is a random subset of [n] where each k∈ [n] is included in Li,j independently with probability p for each i, j∈ [n], then asymptotically almost surely there is an order-n Latin square in which the entry in the ith row and jth column lies in Li,j. The problem of determining the threshold probability for the existence of an order-n Latin square was raised independently by Johansson, by Luria and Simkin, and by Casselgren and H\"aggkvist; our result provides an upper bound which is tight up to a factor of n and strengthens the bound recently obtained by Sah, Sawhney, and Simkin. We also prove analogous results for Steiner triple systems and 1-factorizations of complete graphs, and moreover, we show that each of these thresholds is at most the threshold for the existence of a 1-factorization of a nearly complete regular bipartite graph.