Packing Hamilton Cycles in Cores of Random Graphs

Abstract

Consider the random graph process \Gt\t≥ 0. For k≥ 3 let Gt(k) denote the k-core of Gt and let τk be the minimum t such that the k-core of Gt is nonempty. It is well known that w.h.p. for Gτk(k) has linear size while it is believed to be Hamiltonian. Bollob\'as, Cooper, Fenner and Frieze further conjectured that w.h.p. Gt(k) spans k-12 edge-disjoint Hamilton cycles plus, when k is even, a perfect matching for t≥ τk. We prove that w.h.p.\@ if k is odd then Gt(k) spans k-32 edge disjoint Hamilton cycles plus an additional 2-factor whereas if k is even then it spans k-22 edge disjoint Hamilton cycles plus an additional matching of size n/2-o(n) for t≥ τk. In particular w.h.p. Gt(k) is Hamiltonian for k≥ 4 and t≥ τk. This improves upon results of Krivelevich, Lubetzky and Sudakov.