Lederer, P. L., Lehrenfeld, C., & Schöberl, J. (2020). Divergence-free tangential finite element methods for incompressible flows on surfaces. International Journal for Numerical Methods in Engineering, 121(11), 2503–2533. https://doi.org/10.1002/nme.6317
E101-03 - Forschungsbereich Scientific Computing and Modelling
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Zeitschrift:
International Journal for Numerical Methods in Engineering
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ISSN:
0029-5981
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Datum (veröffentlicht):
15-Jun-2020
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Umfang:
31
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Verlag:
WILEY
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Peer Reviewed:
Ja
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Keywords:
Applied Mathematics; General Engineering; Numerical Analysis
en
Abstract:
In this work we consider the numerical solution of incompressible flows on two-dimensional manifolds. Whereas the compatibility demands of the velocity and the pressure spaces are known from the flat case one further has to deal with the approximation of a velocity field that lies only in the tangential space of the given geometry. Abandoning H¹-conformity allows us to construct finite elements which are—due to an application of the Piola transformation—exactly tangential. To reintroduce continuity (in a weak sense) we make use of (hybrid) discontinuous Galerkin techniques. To further improve this approach, H(divΓ)-conforming finite elements can be used to obtain exactly divergence-free velocity solutions. We present several new finite element discretizations. On a number of numerical examples we examine and compare their qualitative properties and accuracy.
