English

Diffusion with resetting in a logarithmic potential

Statistical Mechanics 2020-10-27 v2 Soft Condensed Matter Mathematical Physics math.MP Probability

Abstract

We study the effect of resetting on diffusion in a logarithmic potential. In this model, a particle diffusing in a potential U(x)=U0logxU(x) = U_0\log|x| is reset, i.e., taken back to its initial position, with a constant rate rr. We show that this analytically tractable model system exhibits a series of phase transitions as a function of a single parameter, βU0\beta U_0, the ratio of the strength of the potential to the thermal energy. For βU0<1\beta U_0<-1 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 βU0>1\beta U_0>-1 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 βU0=5\beta U_0=5. Namely, we find that resetting can expedite arrival to the origin when 1<βU0<5-1<\beta U_0<5, but not when βU0>5\beta U_0>5. The results presented herein generalize results for simple diffusion with resetting -- a widely applicable model that is obtained from ours by setting U0=0U_0=0. 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.

Keywords

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}
}
R2 v1 2026-06-23T14:39:11.054Z