A comparative review of peridynamics and phase-field models for engineering fracture mechanics

Patrick Diehl; Robert Lipton; Thomas Wick; Mayank Tyagi

doi:10.1007/s00466-022-02147-0

A comparative review of peridynamics and phase-field models for engineering fracture mechanics

Patrick Diehl, Robert Lipton, Thomas Wick^*, Mayank Tyagi

^*Korrespondierende*r Autor*in für diese Arbeit

Institut für Angewandte Mathematik

Publikation: Beitrag in Fachzeitschrift › Übersichtsarbeit › Forschung › Peer-Review

Abstract

Computational modeling of the initiation and propagation of complex fracture is central to the discipline of engineering fracture mechanics. This review focuses on two promising approaches: phase-field (PF) and peridynamic (PD) models applied to this class of problems. The basic concepts consisting of constitutive models, failure criteria, discretization schemes, and numerical analysis are briefly summarized for both models. Validation against experimental data is essential for all computational methods to demonstrate predictive accuracy. To that end, the Sandia Fracture Challenge and similar experimental data sets where both models could be benchmarked against are showcased. Emphasis is made to converge on common metrics for the evaluation of these two fracture modeling approaches. Both PD and PF models are assessed in terms of their computational effort and predictive capabilities, with their relative advantages and challenges are summarized.

Originalsprache	Englisch
Seiten (von - bis)	1259-1293
Seitenumfang	35
Fachzeitschrift	Computational mechanics
Jahrgang	69
Ausgabenummer	6
Elektronisch veröffentlicht (E-Pub)	18 Feb. 2022
DOIs	https://doi.org/10.1007/s00466-022-02147-0
Publikationsstatus	Veröffentlicht - Juni 2022

ASJC Scopus Sachgebiete

Numerische Mechanik
Meerestechnik
Maschinenbau
Theoretische Informatik und Mathematik
Computational Mathematics
Angewandte Mathematik

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10.1007/s00466-022-02147-0Lizenz: CC BY 4.0

Andere Dateien und Links

Verknüpfung zur Publikation in Scopus

Strukturerhaltende adaptive Enriched Galerkin Methoden für druckgetriebene 3D Phasenfeldmodelle der Rissausbreitung (im Rahmen des Schwerpunktprogramms 1748: Zuverlässige Simulationstechniken in der Festkörpermechanik - Entwicklung nicht konventioneller Diskretisierungsverfahren, mechanische und mathematische Analyse)
Wick, T. (Projektleiter*in (Principal Investigator))
1 März 2018 → 28 Feb. 2021
Projekt: Forschung

Dieses zitieren

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title = "A comparative review of peridynamics and phase-field models for engineering fracture mechanics",

abstract = "Computational modeling of the initiation and propagation of complex fracture is central to the discipline of engineering fracture mechanics. This review focuses on two promising approaches: phase-field (PF) and peridynamic (PD) models applied to this class of problems. The basic concepts consisting of constitutive models, failure criteria, discretization schemes, and numerical analysis are briefly summarized for both models. Validation against experimental data is essential for all computational methods to demonstrate predictive accuracy. To that end, the Sandia Fracture Challenge and similar experimental data sets where both models could be benchmarked against are showcased. Emphasis is made to converge on common metrics for the evaluation of these two fracture modeling approaches. Both PD and PF models are assessed in terms of their computational effort and predictive capabilities, with their relative advantages and challenges are summarized.",

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note = "Funding Information: This work was partly funded by DTIC Contract FA8075-14-D-0002/0007 and the Center of Computation & Technology at Louisiana State University. Authors also thank Dr. Stewart Silling for his comments on the manuscript prior to the submission and the participants of the Workshop on Experimental and Computational Fracture Mechanics and of the Banff International Research Station: Hydraulic Fracturing: Modeling, Simulation, and Experiment for the discussion on peridynamics and phase-field models which provided several ideas for the challenging applications. In addition, we thank Haim Waismann, John Dolbow, Florin Bobaru, Steve Sun, Jinhyun Choo, and Masoud Behzadinasab for their remarks on the preprint. This material is partially based upon work supported by the U. S. Army Research Laboratory and the U. S. Army Research Office under Contract/Grant Number W911NF1610456. TW was partially funded by the the German Research Foundation, Priority Program 1748 (DFG SPP 1748) under the grant number WI4367/2-1 (project number 392587580). ",

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AB - Computational modeling of the initiation and propagation of complex fracture is central to the discipline of engineering fracture mechanics. This review focuses on two promising approaches: phase-field (PF) and peridynamic (PD) models applied to this class of problems. The basic concepts consisting of constitutive models, failure criteria, discretization schemes, and numerical analysis are briefly summarized for both models. Validation against experimental data is essential for all computational methods to demonstrate predictive accuracy. To that end, the Sandia Fracture Challenge and similar experimental data sets where both models could be benchmarked against are showcased. Emphasis is made to converge on common metrics for the evaluation of these two fracture modeling approaches. Both PD and PF models are assessed in terms of their computational effort and predictive capabilities, with their relative advantages and challenges are summarized.

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A comparative review of peridynamics and phase-field models for engineering fracture mechanics

Abstract

ASJC Scopus Sachgebiete

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Andere Dateien und Links

Projekte

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