Stationary states for stable processes with partial resetting

Abstract

We study a d-dimensional stochastic process X which arises from a L\'evy process Y by partial resetting, that is the position of the process X at a Poisson moment equals c times its position right before the moment, and it develops as Y between these two consecutive moments, c ∈ (0, 1). We focus on Y being a strictly α-stable process with α∈ (0,2] having a transition density: We analyze properties of the transition density p of the process X. We establish a series representation of p. We prove its convergence as time goes to infinity (ergodicity), and we show that the limit Y (density of the ergodic measure) can be expressed by means of the transition density of the process Y starting from zero, which results in closed concise formulae for its moments. We show that the process X reaches a non-equilibrium stationary state. Furthermore, we check that p satisfies the Fokker--Planck equation, and we confirm the harmonicity of Y with respect to the adjoint generator. In detail, we discuss the following cases: Brownian motion, isotropic and d-cylindrical α-stable processes for α ∈ (0,2), and α-stable subordinator for α∈ (0,1). We find the asymptotic behavior of p(t;x,y) as t +∞ while (t,y) stays in a certain space-time region. For Brownian motion, we discover a phase transition, that is a change of the asymptotic behavior of p(t;0,y) with respect to Y(y).

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