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Hybrid mimetic finite-difference and virtual element formulation for coupled poromechanics

Andrea Borio, François P. Hamon, Nicola Castelletto, Joshua A. White, Randolph R. Settgast

2021Computer Methods in Applied Mechanics and Engineering26 citationsDOIOpen Access PDF

Abstract

We present a hybrid mimetic finite-difference and virtual element formulation for coupled single-phase poromechanics on unstructured meshes. The key advantage of the scheme is that it is convergent on complex meshes containing highly distorted cells with arbitrary shapes. We use a local pressure-jump stabilization method based on unstructured macro-elements to prevent the development of spurious pressure modes in incompressible problems approaching undrained conditions. A scalable linear solution strategy is obtained using a block-triangular preconditioner designed specifically for the saddle-point systems arising from the proposed discretization. The accuracy and efficiency of our approach are demonstrated numerically on two-dimensional benchmark problems.

Topics & Concepts

DiscretizationPreconditionerFinite element methodPoromechanicsPolygon meshMathematicsMultigrid methodApplied mathematicsSaddleMeshfree methodsBenchmark (surveying)Mathematical optimizationComputer scienceMathematical analysisLinear systemPartial differential equationGeometryEngineeringStructural engineeringPorous mediumGeotechnical engineeringGeographyPorosityGeodesyAdvanced Numerical Methods in Computational MathematicsComputational Fluid Dynamics and AerodynamicsNumerical methods in engineering