2012
DOI: 10.1016/j.jmps.2012.06.014
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Phase-field modeling of crack propagation in piezoelectric and ferroelectric materials with different electromechanical crack conditions

Abstract: a b s t r a c tWe present a family of phase field models for fracture in piezoelectric and ferroelectric materials. These models couple a variational formulation of brittle fracture with, respectively, (1) the linear theory of piezoelectricity, and (2) a Ginzburg Landau model of the ferroelectric microstructure to address the full complexity of the fracture phenomenon in these materials. In these models, both the cracks and the ferroelectric domain walls are represented in a diffuse way by phase fields. The ma… Show more

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Cited by 140 publications
(98 citation statements)
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“…They are also employed in a wide range of applications in applied science and engineering such as fracture [28,40,83], growth of thin films [94] and grain structures [57], image segmentation [11], vesicle bio-membranes [88,97,126] and multi-phase flows [48], to mention a few. This paper also presents another application of phase-field models for microstructure formation and fracture evolution in ferroelectric materials [1,2,3,4,5,6].…”
Section: Phase-field Modelsmentioning
confidence: 99%
See 3 more Smart Citations
“…They are also employed in a wide range of applications in applied science and engineering such as fracture [28,40,83], growth of thin films [94] and grain structures [57], image segmentation [11], vesicle bio-membranes [88,97,126] and multi-phase flows [48], to mention a few. This paper also presents another application of phase-field models for microstructure formation and fracture evolution in ferroelectric materials [1,2,3,4,5,6].…”
Section: Phase-field Modelsmentioning
confidence: 99%
“…We have introduced briefly two coupled phasefield models in Section 3 considering some of these conditions. In this section, we present a general framework in the context of phase-field models, encompassing all the usual crack-face boundary conditions proposed in the literature for electromechanical materials [5]. The phase-field model of brittle fracture introduced briefly in Section 2.4 is viewed as a regularization of Griffith's sharp-crack model.…”
Section: Modeling Of Different Crack-face Boundary Conditionsmentioning
confidence: 99%
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“…Over the last decade phase-field models for fracture [1][2][3][4]-which are closely related to traditional gradient-enhanced damage models [5]-have been successfully applied to a wide range of problems, such as dynamic fracturing [6][7][8][9], large deformation fracturing [10,11], fracturing of electromechanical materials [12,13], cohesive fracturing [14,15], fracturing of thermo-elastic solids [16,17] and many more. The primary advantage of these models is the flexibility with which complex fractures can be simulated, which is a result of the diffuse fracture representation and due to the fact that propagation laws generally follow naturally from energy minimization principles.…”
Section: Introductionmentioning
confidence: 99%