Self-intersection local times of random walks: Exponential moments in subcritical dimensions

Abstract

Fix p>1, not necessarily integer, with p(d-2)<d. We study the p-fold self-intersection local time of a simple random walk on the lattice d up to time t. This is the p-norm of the vector of the walker's local times, t. We derive precise logarithmic asymptotics of the expectation of \θt \|t\|p\ for scales θt>0 that are bounded from above, possibly tending to zero. The speed is identified in terms of mixed powers of t and θt, and the precise rate is characterized in terms of a variational formula, which is in close connection to the Gagliardo-Nirenberg inequality. As a corollary, we obtain a large-deviation principle for \|t\|p/(t rt) for deviation functions rt satisfying t rt[\|t\|p]. Informally, it turns out that the random walk homogeneously squeezes in a t-dependent box with diameter of order t1/d to produce the required amount of self-intersections. Our main tool is an upper bound for the joint density of the local times of the walk.