The unified nonlocal peridynamics-based phase-field damage theory

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Yehui Bie
  • Huilong Ren
  • Hanghang Yan
  • Jiyue Chen

Organisationseinheiten

Externe Organisationen

  • Peking University
  • Hunan University
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer103980
FachzeitschriftTheoretical and Applied Fracture Mechanics
Jahrgang126
Frühes Online-Datum17 Juni 2023
PublikationsstatusVeröffentlicht - Aug. 2023

Abstract

The peridynamic correspondence model is a promising and attractive candidate for the modeling of localized failure in solids, in that it can incorporate many local classical damage constitutive models through introducing a nonlocal averaged deformation gradient. However, the zero-energy mode and the limited bond breaking criterion greatly restrict the potential applications of this correspondence model. To address these two problems, a unified nonlocal peridynamics-based phase-field damage theory is proposed within the framework of thermodynamics. Firstly, the unified correspondence principle for the displacement field is developed on the basis of the energy compensation method in such a way that a new peridynamic deformation gradient, shape matrix and force state are derived and redefined. And then, the proposed principle is applied to derive the nonlocal phase-field damage constitutive model that the general nonlocal phase-field flux, phase-field flow state and phase-field internal force are defined. Moreover, we propose a mixed variational derivative method to obtain the coupled equilibrium governing equation and present the general linearization approach of the proposed peridynamics-based phase-field model (PD-PFM), where the double states for the coupled displacement and phase fields are derived in detail. It will be found that PD-PFM can not only resolve the zero-energy mode existed in the conventional peridynamic correspondence model, but also provide a rational criterion for the breakage of the peridynamic bond. Some representative numerical examples including mixed mode fracture of single-material media and interface fracture of ceramic coating systems are presented for the validation of PD-PFM. The satisfactory results show both quantitative and qualitative agreement with the available experiment.

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The unified nonlocal peridynamics-based phase-field damage theory. / Bie, Yehui; Ren, Huilong; Yan, Hanghang et al.
in: Theoretical and Applied Fracture Mechanics, Jahrgang 126, 103980, 08.2023.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Bie Y, Ren H, Yan H, Chen J. The unified nonlocal peridynamics-based phase-field damage theory. Theoretical and Applied Fracture Mechanics. 2023 Aug;126:103980. Epub 2023 Jun 17. doi: 10.1016/j.tafmec.2023.103980
Bie, Yehui ; Ren, Huilong ; Yan, Hanghang et al. / The unified nonlocal peridynamics-based phase-field damage theory. in: Theoretical and Applied Fracture Mechanics. 2023 ; Jahrgang 126.
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T1 - The unified nonlocal peridynamics-based phase-field damage theory

AU - Bie, Yehui

AU - Ren, Huilong

AU - Yan, Hanghang

AU - Chen, Jiyue

N1 - Funding Information: This work is supported by the National Natural Science Foundation of China (Grant Nos. 11890681 , 12032001 and 11521202 ).

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N2 - The peridynamic correspondence model is a promising and attractive candidate for the modeling of localized failure in solids, in that it can incorporate many local classical damage constitutive models through introducing a nonlocal averaged deformation gradient. However, the zero-energy mode and the limited bond breaking criterion greatly restrict the potential applications of this correspondence model. To address these two problems, a unified nonlocal peridynamics-based phase-field damage theory is proposed within the framework of thermodynamics. Firstly, the unified correspondence principle for the displacement field is developed on the basis of the energy compensation method in such a way that a new peridynamic deformation gradient, shape matrix and force state are derived and redefined. And then, the proposed principle is applied to derive the nonlocal phase-field damage constitutive model that the general nonlocal phase-field flux, phase-field flow state and phase-field internal force are defined. Moreover, we propose a mixed variational derivative method to obtain the coupled equilibrium governing equation and present the general linearization approach of the proposed peridynamics-based phase-field model (PD-PFM), where the double states for the coupled displacement and phase fields are derived in detail. It will be found that PD-PFM can not only resolve the zero-energy mode existed in the conventional peridynamic correspondence model, but also provide a rational criterion for the breakage of the peridynamic bond. Some representative numerical examples including mixed mode fracture of single-material media and interface fracture of ceramic coating systems are presented for the validation of PD-PFM. The satisfactory results show both quantitative and qualitative agreement with the available experiment.

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