A FFT solver for variational phase-field modeling of brittle fracture

The variational phase-field method is an attractive non-local approach of modeling fracture in heterogeneous materials. However, these materials usually require a fine mesh to resolve the fracture process zone. Consequently, the standard finite element solver becomes cumbersome due to the large numb...

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Bibliographic Details
Published in:Computer methods in applied mechanics and engineering Vol. 349; pp. 167 - 190
Main Authors: Chen, Yang, Vasiukov, Dmytro, Gélébart, Lionel, Park, Chung Hae
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01.06.2019
Elsevier BV
Elsevier
Subjects:
Algorithms
Brittle fracture
Coalescing
Continuous fiber composites
Distributed memory
Engineering Sciences
FFT method
Fiber composites
Finite element method
Fixed-point algorithm
Mathematical analysis
Mathematical models
Mechanics
Mechanics of materials
Mesh generation
Numerical prediction
Phase-field model
Phase-field model
Fixed-point algorithm
FFT method
Brittle fracture
ISSN:0045-7825, 1879-2138
Online Access:Get full text
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Summary:The variational phase-field method is an attractive non-local approach of modeling fracture in heterogeneous materials. However, these materials usually require a fine mesh to resolve the fracture process zone. Consequently, the standard finite element solver becomes cumbersome due to the large number of elements in applications with highly heterogeneous materials. Motivated by this limitation, an algorithm based on FFT methods has been introduced in this paper to solve the phase-field model of brittle fracture. Relying on a staggered update scheme, the proposed algorithm solves the fracture problem and mechanical problem separately, both using the FFT technique. It inherits the advantages of classical FFT methods in terms of simplicity of mesh generation and parallel implementation. Introduced within a FFT-based code “AMITEX”, it takes the advantage of massively parallel capabilities associated with a distributed memory implementation. The characteristics of the proposed method are analyzed in a single edge notched specimen benchmark. Representative numerical examples demonstrate that the proposed FFT solver is capable of predicting different crack modes and complex crack configuration, such as crack interaction, branching and coalescence. Finally, a model of an idealized continuous fiber composite with void involving over 32 million voxels is solved, illustrating the potential of the FFT solver in large-scale problems.
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ISSN:0045-7825
1879-2138
DOI:10.1016/j.cma.2019.02.017