Expansion, long cycles, and complete minors in supercritical random subgraphs of the hypercube
Abstract
Analogous to the case of the binomial random graph G(d+1,p), it is known that the behaviour of a random subgraph of a d-dimensional hypercube, where we include each edge independently with probability p, which we denote by Qdp, undergoes a phase transition around the critical value of p=1d. More precisely, standard arguments show that significantly below this value of p, with probability tending to one as d ∞ (whp for short) all components of this graph have order O(d), whereas Ajtai, Koml\'os and Szemer\'edi showed that significantly above this value, in the supercritical regime, whp there is a unique `giant' component of order (2d). In G(d+1,p) much more is known about the complex structure of the random graph which emerges in this supercritical regime. For example, it is known that in this regime whp G(d+1,p) contains paths and cycles of length (d), as well as complete minors of order (d). In this paper we obtain analogous results in Qdp. In particular, we show that for supercritical p, i.e., when p=1+εd for a positive constant ε, whp Qdp contains a cycle of length (2dd3( d)3 ) and a complete minor of order (2d2d3( d)3 ). In order to prove these results, we show that whp the largest component of Qdp has good edge-expansion properties, a result of independent interest. We also consider the genus of Qdp and show that, in this regime of p, whp the genus is (2d).
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