Crack Front Segmentation and Facet Coarsening in Mixed-Mode Fracture

Chih Hung Chen; Tristan Cambonie; Veronique Lazarus; Matteo Nicoli; Antonio J. Pons; Alain Karma

doi:10.1103/PhysRevLett.115.265503

Crack Front Segmentation and Facet Coarsening in Mixed-Mode Fracture

Chih Hung Chen, Tristan Cambonie, Veronique Lazarus, Matteo Nicoli, Antonio J. Pons, Alain Karma

Research output: Contribution to journal › Article › peer-review

Abstract

A planar crack generically segments into an array of "daughter cracks" shaped as tilted facets when loaded with both a tensile stress normal to the crack plane (mode I) and a shear stress parallel to the crack front (mode III). We investigate facet propagation and coarsening using in situ microscopy observations of fracture surfaces at different stages of quasistatic mixed-mode crack propagation and phase-field simulations. The results demonstrate that the bifurcation from propagating a planar to segmented crack front is strongly subcritical, reconciling previous theoretical predictions of linear stability analysis with experimental observations. They further show that facet coarsening is a self-similar process driven by a spatial period-doubling instability of facet arrays.

Original language	English
Article number	265503
Journal	Physical Review Letters
Volume	115
Issue number	26
DOIs	https://doi.org/10.1103/PhysRevLett.115.265503
Publication status	Published - 30 Dec 2015
Externally published	Yes

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title = "Crack Front Segmentation and Facet Coarsening in Mixed-Mode Fracture",

abstract = "A planar crack generically segments into an array of {"}daughter cracks{"} shaped as tilted facets when loaded with both a tensile stress normal to the crack plane (mode I) and a shear stress parallel to the crack front (mode III). We investigate facet propagation and coarsening using in situ microscopy observations of fracture surfaces at different stages of quasistatic mixed-mode crack propagation and phase-field simulations. The results demonstrate that the bifurcation from propagating a planar to segmented crack front is strongly subcritical, reconciling previous theoretical predictions of linear stability analysis with experimental observations. They further show that facet coarsening is a self-similar process driven by a spatial period-doubling instability of facet arrays.",

author = "Chen, \{Chih Hung\} and Tristan Cambonie and Veronique Lazarus and Matteo Nicoli and Pons, \{Antonio J.\} and Alain Karma",

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T1 - Crack Front Segmentation and Facet Coarsening in Mixed-Mode Fracture

AU - Chen, Chih Hung

AU - Cambonie, Tristan

AU - Lazarus, Veronique

AU - Nicoli, Matteo

AU - Pons, Antonio J.

AU - Karma, Alain

PY - 2015/12/30

Y1 - 2015/12/30

N2 - A planar crack generically segments into an array of "daughter cracks" shaped as tilted facets when loaded with both a tensile stress normal to the crack plane (mode I) and a shear stress parallel to the crack front (mode III). We investigate facet propagation and coarsening using in situ microscopy observations of fracture surfaces at different stages of quasistatic mixed-mode crack propagation and phase-field simulations. The results demonstrate that the bifurcation from propagating a planar to segmented crack front is strongly subcritical, reconciling previous theoretical predictions of linear stability analysis with experimental observations. They further show that facet coarsening is a self-similar process driven by a spatial period-doubling instability of facet arrays.

AB - A planar crack generically segments into an array of "daughter cracks" shaped as tilted facets when loaded with both a tensile stress normal to the crack plane (mode I) and a shear stress parallel to the crack front (mode III). We investigate facet propagation and coarsening using in situ microscopy observations of fracture surfaces at different stages of quasistatic mixed-mode crack propagation and phase-field simulations. The results demonstrate that the bifurcation from propagating a planar to segmented crack front is strongly subcritical, reconciling previous theoretical predictions of linear stability analysis with experimental observations. They further show that facet coarsening is a self-similar process driven by a spatial period-doubling instability of facet arrays.

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DO - 10.1103/PhysRevLett.115.265503

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VL - 115

JO - Physical Review Letters

JF - Physical Review Letters

IS - 26

M1 - 265503

ER -

Crack Front Segmentation and Facet Coarsening in Mixed-Mode Fracture

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