Moderate deviations for the volume of the Wiener sausage
Abstract
For a>0,let Wa(t) be the a-neighbourhood of standard Brownian motion in Rd starting at 0 and observed until time t.It is well-known that E|Wa(t)|~kappaa t (t->infty) for d >= 3,with kappaa the Newtonian capacity of the ball with radius a. We prove that limt->infty 1/t(d-2)/dlog P(|Wa(t)|<=bt) = -Ikappaa(b) in (-infty,0) for all 0<b<kappaa and derive a variational representation for the rate function Ikappaa.We show that the optimal strategy to realise the above moderate deviation is for Wa(t) to look like a Swiss cheese: Wa(t) has random holes whose sizes are of order 1 and whose density varies on scale t1/d.The optimal strategy is such that t-1/d Wa(t) is delocalised in the limit as t->infty.This is markedly different from the optimal strategy for large deviations |Wa(t)|<=f(t) with f(t)=o(t),where Wa(t) is known to fill completely a ball of volume f(t) and nothing outside,so that Wa(t) has no holes and f(t)-1/dWa(t) is localised in the limit as t->infty.We give a detailed analysis of the rate function Ikappaa,in particular,its behaviour near the boundary points of (0,kappaa).It turns out that Ikappaa has an infinite slope at kappaa and,remarkably,for d>=5 is nonanalytic at some critical point in (0,kappaa),above which it follows a pure power law.This crossover is associated with a collapse transition in the optimal strategy.We also derive the analogous moderate deviation result for d=2.In this case E|Wa(t)|~2pi t/log t (t->infty),and we prove that limt->infty 1/log t log P(|Wa(t)|<=bt/log t) =-I2pi(b)in (-infty,0) for all 0<b<2pi.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.