Sangam: A Confluence of Knowledge Streams

Immersed and Discontinuous Finite Element Methods

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dc.contributor Mathematics
dc.contributor Adjerid, Slimane
dc.contributor Renardy, Yuriko Y.
dc.contributor Lin, Tao
dc.contributor Gugercin, Serkan
dc.creator Chaabane, Nabil
dc.date 2016-10-12T06:00:17Z
dc.date 2016-10-12T06:00:17Z
dc.date 2015-04-20
dc.date.accessioned 2023-02-28T16:57:45Z
dc.date.available 2023-02-28T16:57:45Z
dc.identifier vt_gsexam:4708
dc.identifier http://hdl.handle.net/10919/73194
dc.identifier.uri http://localhost:8080/xmlui/handle/CUHPOERS/264528
dc.description In this dissertation we prove the superconvergence of the minimal-dissipation local discontinuous Galerkin method for elliptic problems and construct optimal immersed finite element approximations and discontinuous immersed finite element methods for the Stokes interface problem. In the first part we present an error analysis for the minimal dissipation local discontinuous Galerkin method applied to a model elliptic problem on Cartesian meshes when polynomials of degree at most <i>k</i> and an appropriate approximation of the boundary condition are used. This special approximation allows us to achieve <i>k</i> + 1 order of convergence for both the potential and its gradient in the L<sup>2</sup> norm. Here we improve on existing estimates for the solution gradient by a factor &#8730;h. In the second part we present discontinuous immersed finite element (IFE) methods for the Stokes interface problem on Cartesian meshes that does not require the mesh to be aligned with the interface. As such, we allow unfitted meshes that are cut by the interface. Thus, elements may contain more than one fluid. On these unfitted meshes we construct an immersed Q<sub>1</sub>/Q<sub>0</sub> finite element approximation that depends on the location of the interface. We discuss the basic features of the proposed Q<sub>1</sub>/Q<sub>0</sub> IFE basis functions such as the unisolvent property. We present several numerical examples to demonstrate that the proposed IFE approximations applied to solve interface Stokes problems maintain the optimal approximation capability of their standard counterpart applied to solve the homogeneous Stokes problem. Similarly, we also show that discontinuous Galerkin IFE solutions of the Stokes interface problem maintain the optimal convergence rates in both L<sup>2</sup> and broken H<sup>1</sup> norms. Furthermore, we extend our method to solve the axisymmetric Stokes interface problem with a moving interface and test the proposed method by solving several benchmark problems from the literature.
dc.description Ph. D.
dc.format ETD
dc.format application/pdf
dc.format application/pdf
dc.publisher Virginia Tech
dc.rights In Copyright
dc.rights http://rightsstatements.org/vocab/InC/1.0/
dc.subject LDG
dc.subject Stokes interface problem
dc.subject emulsions
dc.subject discontinuous Galerkin
dc.subject Immersed finite element
dc.title Immersed and Discontinuous Finite Element Methods
dc.type Dissertation


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