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Computational Mechanics

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24-07-2019 | Original Paper

A phase-field model for fractures in nearly incompressible solids

Authors: Katrin Mang, Thomas Wick, Winnifried Wollner

Published in: Computational Mechanics | Issue 1/2020

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Abstract

Within this work, we develop a phase-field description for simulating fractures in nearly incompressible materials. It is well-known that low-order approximations generally lead to volume-locking behaviors. We propose an approach that builds on a mixed form of the displacement equation with two unknowns: a displacement field and a hydro-static pressure variable. Corresponding function spaces have to be chosen properly. On the discrete level, stable Taylor–Hood elements are employed for the displacement-pressure system. Two additional variables describe the phase-field solution and the crack irreversibility constraint. Therefore, the final system contains four variables: displacements, pressure, phase-field, and a Lagrange multiplier. The resulting discrete system is nonlinear and solved monolithically with a Newton-type method. Our proposed model is demonstrated by means of several numerical studies based on three numerical tests. First, different finite element choices are compared in order to investigate the influence of higher-order elements in the proposed settings. Further, numerical results including spatial mesh refinement studies and variations in Poisson’s ratio approximating the incompressible limit, are presented.

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Title: A phase-field model for fractures in nearly incompressible solids
Authors: Katrin Mang
Thomas Wick
Winnifried Wollner
Publication date: 24-07-2019
Publisher: Springer Berlin Heidelberg
Published in: Computational Mechanics / Issue 1/2020
Print ISSN: 0178-7675
Electronic ISSN: 1432-0924
DOI: https://doi.org/10.1007/s00466-019-01752-w

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