An accurate integral equation method for simulating multi-phase Stokes flow

We introduce a numerical method based on an integral equation formulation for simulating drops in viscous fluids in the plane. It builds upon the method introduced by Kropinski in 2001 [17], but improves on it by adding an interpolatory quadrature approach for handling near-singular integrals. Such...

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Bibliographic Details
Published in:Journal of computational physics 2015-10, Vol.298, p.145-160
Main Authors: Ojala, Rikard, Tornberg, Anna-Karin
Format: Article
Language:English
Subjects:
Boundaries
Computer simulation
Construction
Immiscible fluids
Integral equations
Integrals
Mathematical models
Near singular integrals
Quadratures
Specialized quadrature
Stokes flow
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Summary:We introduce a numerical method based on an integral equation formulation for simulating drops in viscous fluids in the plane. It builds upon the method introduced by Kropinski in 2001 [17], but improves on it by adding an interpolatory quadrature approach for handling near-singular integrals. Such integrals typically arise when drop boundaries come close to one another, and are difficult to compute accurately using standard quadrature rules. Adapting the interpolatory quadrature method introduced by Helsing and Ojala in 2008 [11] to the current application, very general drop configurations can be handled while still maintaining stability and high accuracy. The performance of the new method is demonstrated by some challenging numerical examples.
ISSN:0021-9991
1090-2716
1090-2716
DOI:10.1016/j.jcp.2015.06.002