First passage of a diffusing particle under stochastic resetting in bounded domains with spherical symmetry

Abstract

We investigate the first passage properties of a Brownian particle diffusing freely inside a d-dimensional sphere with absorbing spherical surface subject to stochastic resetting. We derive the mean time to absorption (MTA) as functions of resetting rate γ and initial distance r of the particle to the center of the sphere. We find that when r>rc there exists a nonzero optimal resetting rate γ opt at which the MTA is a minimum, where rc= d/( d + 4 ) R and R is the radius of sphere. As r increases, γ opt exhibits a continuous transition from zero to nonzero at r=rc. Furthermore, we consider that the particle lies in between two two-dimensional or three-dimensional concentric spheres, and obtain the domain in which resetting expedites the MTA, which is (R1, rc1) (rc2,R2), with R1 and R2 being the radius of inner and outer spheres, respectively. Interestingly, when R1/R2 is less than a critical value, γ opt exhibits a discontinuous transition at r=rc1; otherwise, such a transition is continuous. However, at r=rc2, γ opt always shows a continuous transition.