Encounter-based model of a run-and-tumble particle with stochastic resetting
Abstract
In this paper we analyze the effects of stochastic resetting on an encounter-based model of an unbiased run-and-tumble particle (RTP) confined to the half-line [0,∞) with a partially absorbing wall at x=0. The RTP tumbles at a constant rate α between the velocity states v with v>0. Absorption occurs when the number of collisions with the wall (discrete local time) exceeds a randomly generated threshold with probability distribution (). The extended RTP model has three state variables, namely, particle position X(t)∈ [0,∞), the velocity direction σ(t)∈\-1, 1\, and the discrete local time L(t)∈ N. We initially assume that only X(t) and σ(t) reset at a Poisson rate r, whereas L(t) is not changed. This implies that resetting is not governed by a renewal process. We use the stochastic calculus of jump processes to derive an evolution equation for the joint probability distribution of the triplet (X(t),σ(t),L(t)). This is then used to calculate the mean first passage time (MFPT) by performing a discrete Laplace transform of the evolution equation with respect to the local time. We thus find that the MFPT's only dependence on the distribution is via the mean local time threshold. We also identify parameter regimes in which the MFPT is a unimodal function of both the resetting and tumbling rates. Finally, we consider conditions under which resetting is given by a renewal process and show how the MFPT in the presence of local time resetting depends on the full statistics of .
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