Local resilience of an almost spanning k-cycle in random graphs

Abstract

The famous P\'osa-Seymour conjecture, confirmed in 1998 by Koml\'os, S\'ark\"ozy, and Szemer\'edi, states that for any k ≥ 2, every graph on n vertices with minimum degree kn/(k + 1) contains the k-th power of a Hamilton cycle. We extend this result to a sparse random setting. We show that for every k ≥ 2 there exists C > 0 such that if p ≥ C( n/n)1/k then w.h.p. every subgraph of a random graph Gn, p with minimum degree at least (k/(k + 1) + o(1))np, contains the k-th power of a cycle on at least (1 - o(1))n vertices, improving upon the recent results of Noever and Steger for k = 2, as well as Allen et al. for k ≥ 3. Our result is almost best possible in three ways: for p n-1/k the random graph Gn, p w.h.p. does not contain the k-th power of any long cycle; there exist subgraphs of Gn, p with minimum degree (k/(k + 1) + o(1))np and (p-2) vertices not belonging to triangles; there exist subgraphs of Gn, p with minimum degree (k/(k + 1) - o(1))np which do not contain the k-th power of a cycle on (1 - o(1))n vertices.