Long paths and connectivity in 1-independent random graphs

Abstract

Given a graph G, a probability measure μ on the subsets of the edge set of G is said to be 1-independent if events determined by edge sets that are at graph distance at least 1 apart in G are independent. Call such a probability measure a 1-ipm on G, and denote by Gμ the associated random spanning subgraph of G. Let M1,≥slant p(G) (resp. M1,≤slant p(G)) denote the collection of 1-ipms μ on G for which each edge is included in Gμ with probability at least p (resp. at most p). Let Z2 denote the square integer lattice. Balister and Bollob\'as raised the question of determining the critical value p=p1,c(Z2) such that for all p>p and all μ ∈ M1,≥slant p(Z2), (Z2)μ almost surely contains an infinite component. This can be thought of as asking for a 1-independent analogue of the celebrated Harris--Kesten theorem. In this paper we investigate both this problem and connectivity problems for 1-ipms more generally. We give two lower bounds on p that significantly improve on the previous bounds. Furthermore, motivated by the Russo--Seymour--Welsh lemmas, we define a 1-independent critical probability for long paths and determine its value for the line and ladder lattices. Finally, for finite graphs G we study f1,G(p) (respectively F1,G(p)), the infimum (resp. supremum) over all μ∈ M1,≥slant p(G) (resp. all μ ∈ M1,≤slant p(G)) of the probability that Gμ is connected. We determine f1,G(p) and F1,G(p) exactly when G is a path, a complete graph and a cycle of length at most 5. Many new problems arise from our work, which are discussed in the final section of the paper.