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Main Authors: Ye, Yilin, Chaigneau, Adrien, Grebenkov, Denis S.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.10220
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author Ye, Yilin
Chaigneau, Adrien
Grebenkov, Denis S.
author_facet Ye, Yilin
Chaigneau, Adrien
Grebenkov, Denis S.
contents We propose an efficient numerical approach to simulate the boundary local time of reflected Brownian motion, as well as the time and position of the associated reaction event on a smooth boundary of a Euclidean domain. This approach combines the standard walk-on-spheres algorithm in the bulk with the approximate solution of the escape problem in a boundary layer. In this way, the most time-consuming simulation of multiple reflections on the boundary is replaced by an equivalent escape event. We validate the proposed escape-from-a-layer approach by comparing simulated statistics of the boundary local time with exact results known for simple domains (a disk, a circular annulus, a sphere, a spherical shell) and with the numerical results obtained by a finite-element method in more sophisticated domains. This approach offers a powerful tool for simulating reflected Brownian motion in multi-scale confinements such as porous media or biological environments, and for solving the related partial differential equations. Its applications in the context of diffusion-controlled reactions in chemical physics are discussed.
format Preprint
id arxiv_https___arxiv_org_abs_2411_10220
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Escape-from-a-layer approach for simulating the boundary local time in Euclidean domains
Ye, Yilin
Chaigneau, Adrien
Grebenkov, Denis S.
Computational Physics
Statistical Mechanics
We propose an efficient numerical approach to simulate the boundary local time of reflected Brownian motion, as well as the time and position of the associated reaction event on a smooth boundary of a Euclidean domain. This approach combines the standard walk-on-spheres algorithm in the bulk with the approximate solution of the escape problem in a boundary layer. In this way, the most time-consuming simulation of multiple reflections on the boundary is replaced by an equivalent escape event. We validate the proposed escape-from-a-layer approach by comparing simulated statistics of the boundary local time with exact results known for simple domains (a disk, a circular annulus, a sphere, a spherical shell) and with the numerical results obtained by a finite-element method in more sophisticated domains. This approach offers a powerful tool for simulating reflected Brownian motion in multi-scale confinements such as porous media or biological environments, and for solving the related partial differential equations. Its applications in the context of diffusion-controlled reactions in chemical physics are discussed.
title Escape-from-a-layer approach for simulating the boundary local time in Euclidean domains
topic Computational Physics
Statistical Mechanics
url https://arxiv.org/abs/2411.10220