Phase-field modeling of anisotropic brittle fracture including several damage mechanisms

Bleyer, Jérémy; Alessi, Roberto

doi:10.1016/j.cma.2018.03.012

Cited by 166 publications

(81 citation statements)

References 63 publications

(102 reference statements)

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“…The (exact) solution of the semi-linear problem in (55) is constructed in Appendix C. It reads (56). More precisely, it highlights the anticipation that the convergence ofx to 2 when r → +∞ must result in the point-wise convergence of α ρ to the corresponding α .…”

Section: ρ-Penalization: Optimal Profile For the Linear Modelmentioning

confidence: 99%

“…The final step of the presented analysis is the derivation of the optimal lower bound for r (and, hence, for ρ). As before, we insert (56) into E S (α) in (51) and arrive at…”

Section: ρ-Penalization: Optimal Profile For the Linear Modelmentioning

confidence: 99%

“…(a) Sketch of the reference profile α in(34), α ρ in(56) and the corresponding limiting point x : whenx converges to 2 , the point-wise convergence of α ρ to α is expected; (b) The numerical evidence of the convergence behavior of α ρ to α in terms of the penalty parameter r.…”

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confidence: 99%

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On penalization in variational phase-field models of brittle fracture

Gerasimov

Lorenzis

2019

Computer Methods in Applied Mechanics and Engineering

111

131

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Irreversible evolution is one of the central concepts as well as implementation challenges of both the variational approach to fracture by Francfort and Marigo (1998) and its regularized counterpart by Bourdin, Francfort and Marigo (2000and 2008, which is commonly referred to as a phase-field model of brittle fracture. Irreversibility of the crack phase-field imposed to prevent fracture healing leads to a constrained minimization problem, whose optimality condition is given by a variational inequality. In our study, the irreversibility is handled via penalization. Provided the penalty constant is well-tuned, the penalized formulation is a good approximation to the original one, with the advantage that the induced equality-based weak problem enables a much simpler algorithmic treatment. We propose an analytical procedure for deriving the optimal penalty constant, more precisely, its lower bound, which guarantees a sufficiently accurate enforcement of the crack phase-field irreversibility. Our main tool is the notion of the optimal phase-field profile, as well as the Γ-convergence result. It is shown that the explicit lower bound is a function of two formulation parameters (the fracture toughness and the regularization length scale) but is independent on the problem setup (geometry, boundary conditions etc.) and the formulation ingredients (degradation function, tension-compression split etc.). The optimally-penalized formulation is tested for two benchmark problems, including one with available analytical solution. We also compare our results with those obtained by using the alternative irreversibility technique based on the notion of the history field by .

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Section: ρ-Penalization: Optimal Profile For the Linear Modelmentioning

confidence: 99%

“…The final step of the presented analysis is the derivation of the optimal lower bound for r (and, hence, for ρ). As before, we insert (56) into E S (α) in (51) and arrive at…”

Section: ρ-Penalization: Optimal Profile For the Linear Modelmentioning

confidence: 99%

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On penalization in variational phase-field models of brittle fracture

Gerasimov

Lorenzis

2019

Computer Methods in Applied Mechanics and Engineering

111

131

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“…Variational approaches based on energy minimization constitute a promising tool to overcome this limitation [17,18]. Specifically, the phase field method (PFM) has proven to be efficient technique in modelling brittle fracture [19][20][21], ductile damage [22,23], dynamic fracture [24], fracture properties prediction of nanocomposites [25], fiber cracking and composites delamination [26][27][28], plates and shells [29,30] and hydrogen embrittlement [31,32], among other phenomena. Recently, the success of phase field fracture methods has been extended to modelling cracking in isotropic FGMs by Hirshikesh et al [33].…”

Section: Introductionmentioning

confidence: 99%

Adaptive phase field modelling of crack propagation in orthotropic functionally graded materials

2021

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In this work, we extend the recently proposed adaptive phase field method to model fracture in orthotropic functionally graded materials (FGMs). A recovery type error indicator combined with quadtree decomposition is employed for adaptive mesh refinement. The proposed approach is capable of capturing the fracture process with a localized mesh refinement that provides notable gains in computational efficiency.The implementation is validated against experimental data and other numerical experiments on orthotropic materials with different material orientations. The results reveal an increase in the stiffness and the maximum force with increasing material orientation angle. The study is then extended to the analysis of orthotropic FGMs. It is observed that, if the gradation in fracture properties is neglected, the material gradient plays a secondary role, with the fracture behaviour being dominated by the orthotropy of the material. However, when the toughness increases along the crack propagation path, a substantial gain in fracture resistance is observed.

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“…Variational approaches based on energy minimization constitute a promising tool to overcome this limitation and could, therefore, be particularly useful in modelling crack advance in FGMs [15][16][17]. Specifically, the phase field method has proven to be a compelling technique in modelling brittle fracture [18,19], ductile damage [20,21], fiber cracking and composites delamination [22,23], and hydrogen embrittlement [24,25], among other phenomena. We aim at extending this success by presenting a phase field formulation for fracture in compositionally graded materials.…”

Section: Introductionmentioning

confidence: 99%

Phase field modelling of crack propagation in functionally graded materials

Hirshikesh

Natarajan

Annabattula

et al. 2019

Composites Part B: Engineering

165

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We present a phase field formulation for fracture in functionally graded materials (FGMs). The model builds upon homogenization theory and accounts for the spatial variation of elastic and fracture properties. Several paradigmatic case studies are addressed to demonstrate the potential of the proposed modelling framework. Specifically, we (i) gain insight into the crack growth resistance of FGMs by conducting numerical experiments over a wide range of material gradation profiles and orientations, (ii) accurately reproduce the crack trajectories observed in graded photodegradable copolymers and glass-filled epoxy FGMs, (iii) benchmark our predictions with results from alternative numerical methodologies, and (iv) model complex crack paths and failure in three dimensional functionally graded solids. The suitability of phase field fracture methods in capturing the crack deflections intrinsic to crack tip mode-mixity due to material gradients is demonstrated. Material gradient profiles that prevent unstable fracture and enhance crack growth resistance are identified: this provides the foundation for the design of fracture resistant FGMs. The finite element code developed can be downloaded from www.empaneda.com/codes.

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Phase-field modeling of anisotropic brittle fracture including several damage mechanisms

Cited by 166 publications

References 63 publications

On penalization in variational phase-field models of brittle fracture

On penalization in variational phase-field models of brittle fracture

Adaptive phase field modelling of crack propagation in orthotropic functionally graded materials

Phase field modelling of crack propagation in functionally graded materials

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