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An unfitted Eulerian finite element method for the time-dependent Stokes problem on moving domains

Henry von Wahl, Thomas Richter, Christoph Lehrenfeld

2021IMA Journal of Numerical Analysis34 citationsDOIOpen Access PDF

Abstract

Abstract We analyse a Eulerian finite element method, combining a Eulerian time-stepping scheme applied to the time-dependent Stokes equations with the CutFEM approach using inf-sup stable Taylor–Hood elements for the spatial discretization. This is based on the method introduced by Lehrenfeld & Olshanskii (2019, A Eulerian finite element method for PDEs in time-dependent domains. ESAIM: M2AN, 53, 585–614) in the context of a scalar convection–diffusion problems on moving domains, and extended to the nonstationary Stokes problem on moving domains by Burman et al. (2019, arXiv:1910.03054 [math.NA]) using stabilized equal-order elements. The analysis includes the geometrical error made by integrating over approximated level set domains in the discrete CutFEM setting. The method is implemented and the theoretical results are illustrated using numerical examples.

Topics & Concepts

Eulerian pathDiscretizationMathematicsFinite element methodScalar (mathematics)Context (archaeology)Mathematical analysisApplied mathematicsConvection–diffusion equationGeometryLagrangianPhysicsPaleontologyBiologyThermodynamicsAdvanced Numerical Methods in Computational MathematicsAdvanced Mathematical Modeling in EngineeringElectromagnetic Simulation and Numerical Methods