First exit times for L\'evy-driven diffusions with exponentially light jumps

Abstract

We consider a dynamical system described by the differential equation Yt=-U'(Yt) with a unique stable point at the origin. We perturb the system by the L\'evy noise of intensity to obtain the stochastic differential equation dXt=-U'(Xt-) dt+ dLt. The process L is a symmetric L\'evy process whose jump measure has exponentially light tails, ([u,∞))(-uα), α>0, u ∞. We study the first exit problem for the trajectories of the solutions of the stochastic differential equation from the interval (-1,1). In the small noise limit 0, the law of the first exit time σx, x∈(-1,1), has exponential tail and the mean value exhibiting an intriguing phase transition at the critical index α=1, namely, Eσ-α for 0<α<1, whereas Eσ- 1||1-1/α for α>1.