"We study Hamiltonicity in random subgraphs of the hypercube Qn. Our first main theorem is an optimal hitting time result. Consider the random process which includes the edges of Qn according to a uniformly chosen random ordering. Then, with high probability, as soon as the graph produced by this process has minimum degree 2k, it contains k edge-disjoint Hamilton cycles, for any fixed k N. Secondly, we obtain a perturbation result: if H Qn satisfies (H) n with 0 fixed and we consider a random binomial subgraph Qnp of Qn with p (0, 1] fixed, then with high probability HQnp contains k edge-disjoint Hamilton cycles, for any fixed k N. In particular, both results resolve a long standing conjecture, posed e.g. by Bollobas, that the threshold probability for Hamiltonicity in the random binomial subgraph of the hypercube equals 1/2. Our techniques also show that, with high probability, for all fixed p (0, 1] the graph Qnp contains an almost spanning cycle. Our methods involve branching processes, the Rodl nibble, and absorption"-- Provided by publisher.
Chapters
1. Introduction
2. Outline of the main proofs
3. Notation
4. Probabilistic tools
5. Auxiliary results
6. Tiling random subgraphs of the hypercube with small cubes
7. Near-spanning trees in random subgraphs of the hypercube
8. Hamilton cycles in randomly perturbed dense subgraphs of the hypercube
9. Hitting time result
Padraig Condon, University of Birmingham, United Kingdom, Alberto Espuny Diaz, University of Birmingham, United Kingdom, Antonio Girao, University of Birmingham, United Kingdom, Daniela Kuhn, University of Birmingham, United Kingdom, and Deryk Osthus, University of Birmingham, United Kingdom
