From one-dimensional diffusion processes metastable behaviour to parabolic equations asymptotics

Abstract

Consider the one-dimensional elliptic operator given by equation* (Lε f)(x) \;=\; b (x) \, f'(x) \,+\, ε\, a (x)\, f''(x) \;, equation* where the drift b R R and the diffusion coefficient a R R are periodic C1(R) functions satisfying further conditions, and ε>0. Consider the initial-valued problem equation* \ aligned & ∂t\,uε\,=\,Lε\,uε\;,\\ & uε(0,\,·)=u0(·)\;, aligned .equation* for some bounded continuous function u0. We prove the existence of time-scales θε(1),\,…,\,θε(q) such that θε(1)∞, θε(p+1)/θε(p)∞, 1 pq-1, probability measures p(x,·), x∈ R, and kernels Rt(p)(mj,mk), where \mj:j∈ Z\ represents the set of stable equilibrium of the ODE x(t) = b(x(t)) such that equation* ε0 uε(tθε(p), x) \;=\;Σj,k∈ Z p(x,mj)\, Rt(p) (mj,mk) \,u0(mk)\;, equation* for all t>0 and x∈ R. The solution uε asymptotic behavior description is completed by the characterisation of its behaviour in the intermediate time-scales ε such that ε/θε(p)∞, ε/θε(p+1)0 for some 0 pq, where θε(0)=1, θε(q+1)=+∞. The proof relies on the analysis of the diffusion Xε(·) induced by the generator Lε based on the resolvent approach to metastability introduced in [21].