A robust Nitsche’s formulation for interface problems

► Robust Nitsche’s method for “jump”-type constraints developed for embedded finite element methods. ► Established a relationship between weights in the consistency terms and stability. ► Robustness demonstrated through numerical performance with particular emphasis on interfacial quantities. In thi...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering 2012-06, Vol.225-228, p.44-54
Main Authors: Annavarapu, Chandrasekhar, Hautefeuille, Martin, Dolbow, John E.
Format: Article
Language:English
Subjects:
Discontinuous Galerkin
Embedded interface
Engineering Sciences
Exact sciences and technology
Fundamental areas of phenomenology (including applications)
Mathematics
Mechanics
Nitsche
Numerical analysis
Numerical analysis. Scientific computation
Partial differential equations, initial value problems and time-dependant initial-boundary value problems
Physics
Sciences and techniques of general use
Solid mechanics
Stabilized
Structural and continuum mechanics
Structural mechanics
X-FEM
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Summary:► Robust Nitsche’s method for “jump”-type constraints developed for embedded finite element methods. ► Established a relationship between weights in the consistency terms and stability. ► Robustness demonstrated through numerical performance with particular emphasis on interfacial quantities. In this work, we propose a novel weighting for the interfacial consistency terms arising in a Nitsche variational form. We demonstrate through numerical analysis and extensive numerical evidence that the choice of the weighting parameter has a great bearing on the stability of the method. Consequently, we propose a weighting that results in an estimate for the stabilization parameter such that the method remains well behaved in varied settings; ranging from the configuration of embedded interfaces resulting in arbitrarily small elements to such cases where a large contrast in material properties exists. An important consequence of this weighting is that the bulk as well as the interfacial fields remain well behaved in the presence of (a) elements with arbitrarily small volume fractions, (b) large material heterogeneities and (c) both large heterogeneities as well as arbitrarily small elements. We then highlight the accuracy and efficiency of the proposed formulation through numerical examples, focusing particular attention on interfacial quantities of interest.
ISSN:0045-7825
1879-2138
DOI:10.1016/j.cma.2012.03.008