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Main Authors: Wang, Haiyang, Fryklund, Fredrik, Potter, Samuel, Greengard, Leslie
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.12500
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author Wang, Haiyang
Fryklund, Fredrik
Potter, Samuel
Greengard, Leslie
author_facet Wang, Haiyang
Fryklund, Fredrik
Potter, Samuel
Greengard, Leslie
contents Slow, viscous flow in branched structures arises in many biological and engineering settings. Direct numerical simulation of flow in such complicated multi-scale geometry, however, is a computationally intensive task. We propose a scattering theory framework that dramatically reduces this cost by decomposing networks into components connected by short straight channels. Exploiting the phenomenon of rapid return to Poiseuille flow (Saint-Venant's principle in the context of elasticity), we compute a high-order accurate scattering matrix for each component via boundary integral equations. These precomputed components can then be assembled into arbitrary branched structures, and the precomputed local solutions on each component can be assembled into an accurate global solution. The method is modular, has negligible cost, and appears to be the first full-fidelity solver that makes use of the return to Poiseuille flow phenomenon. In our two-dimensional examples, it matches the accuracy of full-domain solvers while requiring only a fraction of the computational effort.
format Preprint
id arxiv_https___arxiv_org_abs_2509_12500
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Scattering theory for Stokes flow in complex branched structures
Wang, Haiyang
Fryklund, Fredrik
Potter, Samuel
Greengard, Leslie
Numerical Analysis
Fluid Dynamics
Slow, viscous flow in branched structures arises in many biological and engineering settings. Direct numerical simulation of flow in such complicated multi-scale geometry, however, is a computationally intensive task. We propose a scattering theory framework that dramatically reduces this cost by decomposing networks into components connected by short straight channels. Exploiting the phenomenon of rapid return to Poiseuille flow (Saint-Venant's principle in the context of elasticity), we compute a high-order accurate scattering matrix for each component via boundary integral equations. These precomputed components can then be assembled into arbitrary branched structures, and the precomputed local solutions on each component can be assembled into an accurate global solution. The method is modular, has negligible cost, and appears to be the first full-fidelity solver that makes use of the return to Poiseuille flow phenomenon. In our two-dimensional examples, it matches the accuracy of full-domain solvers while requiring only a fraction of the computational effort.
title Scattering theory for Stokes flow in complex branched structures
topic Numerical Analysis
Fluid Dynamics
url https://arxiv.org/abs/2509.12500