Limit theorems for additive functionals of continuous time random walks

Abstract

For a continuous-time random walk X=\Xt,t 0\ (in general non-Markov), we study the asymptotic behavior, as t→ ∞, of the normalized additive functional ct∫0t f(Xs)ds, t 0. Similarly to the Markov situation, assuming that the distribution of jumps of X belongs to the domain of attraction to α-stable law with α>1, we establish the convergence to the local time at zero of an α-stable L\'evy motion. We further study a situation where X is delayed by a random environment given by the Poisson shot-noise potential: (x,γ)= e-Σy∈ γ φ(x-y), where φ R [0,∞) is a bounded function decaying sufficiently fast, and γ is a homogeneous Poisson point process, independent of X. We find that in this case the weak limit has both "quenched" component depending on , and a component, where is "averaged".