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A fast numerical method for ideal fluid flow in domains with multiple stirrers

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Published 7 February 2018 © 2018 IOP Publishing Ltd & London Mathematical Society
, , Citation Mohamed M S Nasser and Christopher C Green 2018 Nonlinearity 31 815 DOI 10.1088/1361-6544/aa99a5

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Author e-mails

mms.nasser@qu.edu.qa

christopher.c.green@mq.edu.au

Author affiliations

1 Department of Mathematics, Statistics & Physics, Qatar University, PO Box 2713, Doha, Qatar

2 Department of Mathematics, Macquarie University, Sydney NSW 2109, Australia

Author notes

3 Author to whom any correspondence should be addressed.

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Dates

  1. Received 15 November 2016
  2. Accepted 10 November 2017
  3. Published

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0951-7715/31/3/815

Abstract

A collection of arbitrarily-shaped solid objects, each moving at a constant speed, can be used to mix or stir ideal fluid, and can give rise to interesting flow patterns. Assuming these systems of fluid stirrers are two-dimensional, the mathematical problem of resolving the flow field—given a particular distribution of any finite number of stirrers of specified shape and speed—can be formulated as a Riemann–Hilbert (R–H) problem. We show that this R–H problem can be solved numerically using a fast and accurate algorithm for any finite number of stirrers based around a boundary integral equation with the generalized Neumann kernel. Various systems of fluid stirrers are considered, and our numerical scheme is shown to handle highly multiply connected domains (i.e. systems of many fluid stirrers) with minimal computational expense.

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10.1088/1361-6544/aa99a5