A direct Poisson solver in spherical geometry with an application to diffusiophoretic problems

Te Sheng Lin; Wei Fan Hu; Chaouqi Misbah

doi:10.1016/j.jcp.2020.109362

A direct Poisson solver in spherical geometry with an application to diffusiophoretic problems

Te Sheng Lin, Wei Fan Hu, Chaouqi Misbah

Department of Mathematics

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

We propose a simple and efficient class of direct solvers for Poisson equation in finite or infinite domains related to spherical geometry. The solver was developed based on truncated spherical harmonics expansion, where the differential mode equations were solved by second-order finite difference method without handling coordinate singularities. The solver was further extended to study the dynamics of a diffusiophoretic particle suspended in Stokes flow. Numerical experiments suggested that the particle can achieve a self-sustained unidirectional motion at moderate Péclet numbers, whereas the particle motion becomes chaotic in high Péclet number regimes. The statistical analysis illustrates the run-and-tumble-like nature at short times and diffusive nature at long times without any source of noise.

Original language	English
Article number	109362
Journal	Journal of Computational Physics
Volume	409
DOIs	https://doi.org/10.1016/j.jcp.2020.109362
State	Published - 15 May 2020

Keywords

Diffusiophoresis
Fast Poisson solver
Microswimmer
Spherical harmonics expansion

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10.1016/j.jcp.2020.109362

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title = "A direct Poisson solver in spherical geometry with an application to diffusiophoretic problems",

abstract = "We propose a simple and efficient class of direct solvers for Poisson equation in finite or infinite domains related to spherical geometry. The solver was developed based on truncated spherical harmonics expansion, where the differential mode equations were solved by second-order finite difference method without handling coordinate singularities. The solver was further extended to study the dynamics of a diffusiophoretic particle suspended in Stokes flow. Numerical experiments suggested that the particle can achieve a self-sustained unidirectional motion at moderate P{\'e}clet numbers, whereas the particle motion becomes chaotic in high P{\'e}clet number regimes. The statistical analysis illustrates the run-and-tumble-like nature at short times and diffusive nature at long times without any source of noise.",

keywords = "Diffusiophoresis, Fast Poisson solver, Microswimmer, Spherical harmonics expansion",

author = "Lin, {Te Sheng} and Hu, {Wei Fan} and Chaouqi Misbah",

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T1 - A direct Poisson solver in spherical geometry with an application to diffusiophoretic problems

AU - Lin, Te Sheng

AU - Hu, Wei Fan

AU - Misbah, Chaouqi

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Y1 - 2020/5/15

N2 - We propose a simple and efficient class of direct solvers for Poisson equation in finite or infinite domains related to spherical geometry. The solver was developed based on truncated spherical harmonics expansion, where the differential mode equations were solved by second-order finite difference method without handling coordinate singularities. The solver was further extended to study the dynamics of a diffusiophoretic particle suspended in Stokes flow. Numerical experiments suggested that the particle can achieve a self-sustained unidirectional motion at moderate Péclet numbers, whereas the particle motion becomes chaotic in high Péclet number regimes. The statistical analysis illustrates the run-and-tumble-like nature at short times and diffusive nature at long times without any source of noise.

AB - We propose a simple and efficient class of direct solvers for Poisson equation in finite or infinite domains related to spherical geometry. The solver was developed based on truncated spherical harmonics expansion, where the differential mode equations were solved by second-order finite difference method without handling coordinate singularities. The solver was further extended to study the dynamics of a diffusiophoretic particle suspended in Stokes flow. Numerical experiments suggested that the particle can achieve a self-sustained unidirectional motion at moderate Péclet numbers, whereas the particle motion becomes chaotic in high Péclet number regimes. The statistical analysis illustrates the run-and-tumble-like nature at short times and diffusive nature at long times without any source of noise.

KW - Diffusiophoresis

KW - Fast Poisson solver

KW - Microswimmer

KW - Spherical harmonics expansion

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DO - 10.1016/j.jcp.2020.109362

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VL - 409

JO - Journal of Computational Physics

JF - Journal of Computational Physics

M1 - 109362

ER -

A direct Poisson solver in spherical geometry with an application to diffusiophoretic problems

Abstract

Keywords

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