Diffusion with resetting in a logarithmic potential
Abstract
We study the effect of resetting on diffusion in a logarithmic potential. In this model, a particle diffusing in a potential is reset, i.e., taken back to its initial position, with a constant rate . We show that this analytically tractable model system exhibits a series of phase transitions as a function of a single parameter, , the ratio of the strength of the potential to the thermal energy. For the potential is strongly repulsive, preventing the particle from reaching the origin. Resetting then generates a non-equilibrium steady state which is characterized exactly and thoroughly analyzed. In contrast, for the potential is either weakly repulsive or attractive and the diffusing particle eventually reaches the origin. In this case, we provide a closed form expression for the subsequent first-passage time distribution and show that a resetting transition occurs at . Namely, we find that resetting can expedite arrival to the origin when , but not when . The results presented herein generalize results for simple diffusion with resetting -- a widely applicable model that is obtained from ours by setting . Extending to general potential strengths, our work opens the door to theoretical and experimental investigation of a plethora of problems that bring together resetting and diffusion in logarithmic potential.
Cite
@article{arxiv.2004.01898,
title = {Diffusion with resetting in a logarithmic potential},
author = {Somrita Ray and Shlomi Reuveni},
journal= {arXiv preprint arXiv:2004.01898},
year = {2020}
}