Asymptotics for Exit Problem and Principal Eigenvalue for a Class of Non-Local Elliptic Operators Related to Diffusion Processes with Random Jumps and Vanishing Diffusion

Abstract

Let D⊂ Rd be a bounded domain and denote by P(D) the space of probability measures on D. Let equation* L=12∇· a∇ +b∇ equation* be a second order elliptic operator. Let μ∈ P(D) and δ>0. Consider a Markov process X(t) in D which performs diffusion in D generated by the operator δ L and is stopped at the boundary, and which while running, jumps instantaneously, according to an exponential clock with spatially dependent intensity V>0, to a new point, according to the distribution μ. The Markov process is generated by the operator Lδ,μ, V defined by equation* Lδ,μ, Vφ δ L φ+V(∫Dφ dμ-φ). equation* %where Cμ is the % "μ-centering" operator defined by %equation* %Cμ(φ)=φ-∫Dφ dμ. %equation* Let φδ,μ,V denote the solution to the Dirichlet problem equation*Dirprob aligned &Lδ,μ,Vφ=0\ in\ D;\\ &φ=f\ on\ ∂ D, aligned equation* where f is continuous. The solution has the stochastic representation equation* φδ,μ,V(x)=Exf(X(τD)). equation* One has that φ0,μ,V(f)δ0φδ,μ,V(x) is independent of x∈ D. We evaluate this constant in the case that μ has a density in a neighborhood of ∂ D. We also study the asymptotic behavior as δ0 of the principal eigenvalue λ0(δ,μ,V) for the operator Lδ,μ, V, which generalizes previously obtained results for the case L=12 .