Some inequalities for reversible Markov chains and branching random walks via spectral optimization

Abstract

We present results relating mixing times to the intersection time of branching random walk (BRW) in which the logarithm of the expected number of particles grows at rate of the spectral-gap gap . This is a finite state space analog of a critical branching process. Namely, we show that the maximal expected hitting time of a state by such a BRW is up to a universal constant larger than the L∞ mixing-time, whereas under transitivity the same is true for the intersection time of two independent such BRWs. Using the same methodology, we show that for a sequence of reversible Markov chains, the L∞ mixing-times tmix(∞) are of smaller order than the maximal hitting times thit iff the product of the spectral-gap and thit diverges, by establishing the inequality tmix(∞) 1gap(ethit · gap) . This resolves a conjecture of Aldous and Fill (Reversible Markov chains and random walks on graphs, Open Problem 14.12) asserting that under transitivity the condition that thit 1gap implies mean-field behavior for the coalescing time of coalescing random walks.