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Main Authors: Debnath, Tanwi, Chaudhury, Pinaki, Mukherjee, Taritra, Mondal, Debasish, Ghosh, Pulak K.
Format: Preprint
Published: 2021
Subjects:
Online Access:https://arxiv.org/abs/2111.01324
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author Debnath, Tanwi
Chaudhury, Pinaki
Mukherjee, Taritra
Mondal, Debasish
Ghosh, Pulak K.
author_facet Debnath, Tanwi
Chaudhury, Pinaki
Mukherjee, Taritra
Mondal, Debasish
Ghosh, Pulak K.
contents We numerically investigate the mean exit time of an inertial active Brownian particle from a circular cavity with single or multiple exit windows. Our simulation results witness distinct escape mechanisms depending upon the relative amplitudes of the thermal length and self-propulsion length compared to the cavity and pore sizes. For exceedingly large self-propulsion lengths, overdamped active particles diffuse on the cavity surface, and rotational dynamics solely governs the exit process. On the other hand, the escape kinetics of a very weakly damped active particle is largely dictated by bouncing effects on the cavity walls irrespective of the amplitude of self-propulsion persistence lengths. We show that the exit rate can be maximized for an optimal self-propulsion persistence length, which depends on the damping strength, self-propulsion velocity, and cavity size. However, the optimal persistence length is insensitive to the opening windows' size, number, and arrangement. Numerical results have been interpreted analytically based on qualitative arguments. The present analysis aims to understand the transport controlling mechanism of active matter in confined structures.
format Preprint
id arxiv_https___arxiv_org_abs_2111_01324
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Escape kinetics of self-propelled particles from a circular cavity
Debnath, Tanwi
Chaudhury, Pinaki
Mukherjee, Taritra
Mondal, Debasish
Ghosh, Pulak K.
Statistical Mechanics
Article
We numerically investigate the mean exit time of an inertial active Brownian particle from a circular cavity with single or multiple exit windows. Our simulation results witness distinct escape mechanisms depending upon the relative amplitudes of the thermal length and self-propulsion length compared to the cavity and pore sizes. For exceedingly large self-propulsion lengths, overdamped active particles diffuse on the cavity surface, and rotational dynamics solely governs the exit process. On the other hand, the escape kinetics of a very weakly damped active particle is largely dictated by bouncing effects on the cavity walls irrespective of the amplitude of self-propulsion persistence lengths. We show that the exit rate can be maximized for an optimal self-propulsion persistence length, which depends on the damping strength, self-propulsion velocity, and cavity size. However, the optimal persistence length is insensitive to the opening windows' size, number, and arrangement. Numerical results have been interpreted analytically based on qualitative arguments. The present analysis aims to understand the transport controlling mechanism of active matter in confined structures.
title Escape kinetics of self-propelled particles from a circular cavity
topic Statistical Mechanics
Article
url https://arxiv.org/abs/2111.01324