Local resilience for squares of almost spanning cycles in sparse random graphs

Abstract

In 1962, P\'osa conjectured that a graph G=(V, E) contains a square of a Hamiltonian cycle if δ(G) 2n/3. Only more than thirty years later Koml\'os, S\'arkozy, and Szemer\'edi proved this conjecture using the so-called Blow-Up Lemma. Here we extend their result to a random graph setting. We show that for every ε > 0 and p=n-1/2+ε a.a.s. every subgraph of Gn,p with minimum degree at least (2/3+ε)np contains the square of a cycle on (1-o(1))n vertices. This is almost best possible in three ways: (1) for p n-1/2 the random graph will not contain any square of a long cycle (2) one cannot hope for a resilience version for the square of a spanning cycle (as deleting all edges in the neighborhood of single vertex destroys this property) and (3) for c<2/3 a.a.s. Gn,p contains a subgraph with minimum degree at least cnp which does not contain the square of a path on (1/3+c)n vertices.