A phase-field formulation for dynamic cohesive fracture

Geelen, Rudy; Liu, Yingjie; Hu, Tianchen; Tupek, Michael R.; Dolbow, John E.

doi:10.1016/j.cma.2019.01.026

Cited by 172 publications

(113 citation statements)

References 61 publications

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“…For the quasi-static case, other forms of degradation functions in PFM have been recently proposed to increase the accuracy in predicting the critical loads associated with crack nucleation and preserving the linear elastic response in the bulk material prior to fracture [94]. These degradation functions avoid a noticeable localization of the phase field before the nucleation of a crack [95][96][97] or approximate a cohesive-type response for materials that exhibit some ductility after reaching their ultimate strength [98]. We have not investigated whether these newer PF models improve upon the results shown here.…”

Section: Time Of Crack Branchingmentioning

confidence: 99%

Comparison of peridynamic and phase-field models for dynamic brittle fracture in glassy materials

Mehrmashhadi¹,

Bahadori²,

Bobaru³

2020

Preprint

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We report computational results obtained with three different models for dynamic brittle fracture. The results are compared against recent experimental tests on dynamic fracture/crack branching in glass induced by impact. Two peridynamic models (one using the meshfree discretization, the other being the LS-DYNA’s discontinuous-Galerkin implementation) and a phase-field model lead to interesting and important differences in terms of reproducing the experimentally observed fracture behavior and crack paths. We monitor the crack branching location, the angle of crack branching, the crack propagation speed, and some particular features seen in the experimental crack paths: small twists/kinks near the far edge of the sample. We discuss the models’ performance and provide possible reasons behind the failure of some of the models to correctly predict the observed behavior.

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Section: Time Of Crack Branchingmentioning

confidence: 99%

Comparison of peridynamic and phase-field models for dynamic brittle fracture in glassy materials

Mehrmashhadi¹,

Bahadori²,

Bobaru³

2020

Preprint

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“…There have been several recent efforts emphasizing the requirement of a generalized cohesive description of fracture using the phase field method [250,251], see, also Lorentz [252]. More specifically, Wu and Nguyen [251] proposed a unified phase field theory, namely the PF-CZM, for brittle and quasi-brittle fractures which converges to a cohesive zone model within the limits of a vanishing length-scale parameter.…”

Section: Overviewmentioning

confidence: 99%

“…PF-CZM was compared to the XFEM in [253] and further extended to the case of dynamic fracture in [254]. Furthermore, Geelen et al [250] extended the work introduced in [255] to a dynamic cohesive fracture model incorporating phase field formulations.…”

Section: Overviewmentioning

confidence: 99%

“…Higher values of the length-scale parameter lead to lower peak forces and vice versa. In recent formulations, see, e.g., Wu and Nguyen [251] and Geelen et al [250] this is alleviated, hence providing a significant advantage in enhancing the critical-stress predicting capabilities of the phase field method. In Miehe et al [256], generalized crack-driving forces with a failure criteria based on the maximum principal stress were introduced which also succeeded in predicting critical fracture loads unaffected by the length-scale parameter.…”

Section: Pfm Variational Formulationmentioning

confidence: 99%

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Discrete and Phase Field Methods for Linear Elastic Fracture Mechanics: A Comparative Study and State-of-the-Art Review

et al. 2019

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Three alternative approaches, namely the extended/generalized finite element method (XFEM/GFEM), the scaled boundary finite element method (SBFEM) and phase field methods, are surveyed and compared in the context of linear elastic fracture mechanics (LEFM). The purpose of the study is to provide a critical literature review, emphasizing on the mathematical, conceptual and implementation particularities that lead to the specific advantages and disadvantages of each method, as well as to offer numerical examples that help illustrate these features.

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“…To avoid using an auxiliary field, level set methods have also been utilized . Other approaches, which set out to model cohesive fracture rather exploit the variational phase‐field approach to brittle fracture and attempt to obtain a cohesive‐like fracture behavior by modifying the assumed phase‐field distribution perpendicular to the center of the crack, the degradation function, or attempt to reconstruct the crack opening from the phase field …”

Section: Introductionmentioning

confidence: 99%

Considerations on a phase‐field model for adhesive fracture

Motlagh

Borst

2020

Numerical Meth Engineering

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Summary A recently proposed phase‐field model for cohesive fracture is examined. Previous investigations have shown stress oscillations to occur when using unstructured meshes. It is now shown that the use of nonuniform rational B‐splines (NURBS) as basis functions rather than traditional Lagrange polynomials significantly reduces this oscillatory behavior. Moreover, there is no effect on the global structural behavior, as evidenced through load‐displacement curves. The phase‐field model imposes restrictions on the interpolation order of the NURBS used for the three different fields: displacement, phase field, and crack opening. This holds within the Bézier element, but also at the boundaries, where a reduction to 𝒞0‐continuity yields optimal results. Application to a range of cases, including debonding of a hard fiber embedded in a soft matrix, illustrates the potential of the cohesive phase‐field model.

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A phase-field formulation for dynamic cohesive fracture

Cited by 172 publications

References 61 publications

Comparison of peridynamic and phase-field models for dynamic brittle fracture in glassy materials

Comparison of peridynamic and phase-field models for dynamic brittle fracture in glassy materials

Discrete and Phase Field Methods for Linear Elastic Fracture Mechanics: A Comparative Study and State-of-the-Art Review

Considerations on a phase‐field model for adhesive fracture

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