Cutoff for Almost All Random Walks on Abelian Groups

Abstract

Consider the random Cayley graph of a finite group G with respect to k generators chosen uniformly at random, with 1 k |G|; denote it Gk. A conjecture of Aldous and Diaconis (1985) asserts, for k |G|, that the random walk on this graph exhibits cutoff. Further, the cutoff time should be a function only of k and |G|, to sub-leading order. This was verified for all Abelian groups in the '90s. We extend the conjecture to 1 k |G|. We establish cutoff for all Abelian groups under the condition k - d(G) 1, where d(G) is the minimal size of a generating subset of G, which is almost optimal. The cutoff time is described (abstractly) in terms of the entropy of random walk on Zk. This abstract definition allows us to deduce that the cutoff time can be written as a function only of k and |G| when d(G) |G| and k - d(G) k 1; this is not the case when d(G) |G| k. For certain regimes of k, we find the limit profile of the convergence to equilibrium. Wilson (1997) conjectured that Z2d gives rise to the slowest mixing time for Gk amongst all groups of size at most 2d. We give a partial answer, verifying the conjecture for nilpotent groups. This is obtained via a comparison result of independent interest between the mixing times of nilpotent G and a corresponding Abelian group G, namely the direct sum of the Abelian quotients in the lower central series of G. We use this to refine a celebrated result of Alon and Roichman (1994): we show for nilpotent G that Gk is an expander provided k - d( G) |G|. As another consequence, we establish cutoff for nilpotent groups with relatively small commutators, including high-dimensional special groups, such as Heisenberg groups.