Resilience of Perfect Matchings and Hamiltonicity in Random Graph Processes

Abstract

Let \Gi\ be the random graph process: starting with an empty graph G0 with n vertices, in every step i ≥ 1 the graph Gi is formed by taking an edge chosen uniformly at random among the non-existing ones and adding it to the graph Gi - 1. The classical `hitting-time' result of Ajtai, Koml\'os, and Szemer\'edi, and independently Bollob\'as, states that asymptotically almost surely the graph becomes Hamiltonian as soon as the minimum degree reaches 2, that is if δ(Gi) 2 then Gi is Hamiltonian. We establish a resilience version of this result. In particular, we show that the random graph process almost surely creates a sequence of graphs such that for m ≥ (16 + o(1))n n edges, the 2-core of the graph Gm remains Hamiltonian even after an adversary removes (12 - o(1))-fraction of the edges incident to every vertex. A similar result is obtained for perfect matchings.