L2-exponential ergodicity of stochastic Hamiltonian systems with α-stable L\'evy noises

Abstract

Based on the hypocoercivity approach due to Villani Villani, Dolbeault, Mouhot and Schmeiser DMS established a new and simple framework to investigate directly the L2-exponential convergence to the equilibrium for the solution to the kinetic Fokker-Planck equation. Nowadays, the general framework advanced in DMS is named as the DMS framework for hypocoercivity. Subsequently, Grothaus and Stilgenbauer Grothaus builded a dual version of the DMS framework in the kinetic Fokker-Planck setting. No matter what the abstract DMS framework in DMS and the dual counterpart in Grothaus, the densely defined linear operator involved is assumed to be decomposed into two parts, where one part is symmetric and the other part is anti-symmetric. Thus, the existing DMS framework is not applicable to investigate the L2-exponential ergodicity for stochastic Hamiltonian systems with α-stable L\'evy noises, where one part of the associated infinitesimal generators is anti-symmetric whereas the other part is not symmetric. In this paper, we shall develop a dual version of the DMS framework in the fractional kinetic Fokker-Planck setup, where one part of the densely defined linear operator under consideration need not to be symmetric. As a direct application, we explore the L2-exponential ergodicity of stochastic Hamiltonian systems with α-stable L\'evy noises. The proof is also based on Poincar\'e inequalities for non-local stable-like Dirichlet forms and the potential theory for fractional Riesz potentials.