Collaborative Oscillatory Fracture

Juan Francisco Fuentealba; Joel Marthelot; Benoît Roman; Francisco Melo

doi:10.1103/PhysRevLett.124.174102

Collaborative Oscillatory Fracture

Juan Francisco Fuentealba, Joel Marthelot, Benoît Roman, Francisco Melo

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

Abstract

We report a new oscillatory propagation of cracks in thin films where three cracks interact mediated by two delamination fronts. Experimental observations indicate that delamination fronts joining the middle crack to the lateral crack tips swap contact periodically with the crack tip of the middle crack. A model based on a variational approach analytically predicts the condition of propagation and geometrical features of three parallel cracks. The stability conditions and oscillating propagation are found numerically and the predictions are in favorable agreement with experiments. We found that the physical mechanism selecting the wavelength structure is a relaxation process in which the middle crack produces a regular oscillatory path.

Original language	English
Article number	174102
Journal	Physical Review Letters
Volume	124
Issue number	17
DOIs	https://doi.org/10.1103/PhysRevLett.124.174102
Publication status	Published - 1 May 2020
Externally published	Yes

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10.1103/PhysRevLett.124.174102

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title = "Collaborative Oscillatory Fracture",

abstract = "We report a new oscillatory propagation of cracks in thin films where three cracks interact mediated by two delamination fronts. Experimental observations indicate that delamination fronts joining the middle crack to the lateral crack tips swap contact periodically with the crack tip of the middle crack. A model based on a variational approach analytically predicts the condition of propagation and geometrical features of three parallel cracks. The stability conditions and oscillating propagation are found numerically and the predictions are in favorable agreement with experiments. We found that the physical mechanism selecting the wavelength structure is a relaxation process in which the middle crack produces a regular oscillatory path.",

author = "Fuentealba, \{Juan Francisco\} and Joel Marthelot and Beno{\^i}t Roman and Francisco Melo",

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AU - Marthelot, Joel

AU - Roman, Benoît

AU - Melo, Francisco

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N2 - We report a new oscillatory propagation of cracks in thin films where three cracks interact mediated by two delamination fronts. Experimental observations indicate that delamination fronts joining the middle crack to the lateral crack tips swap contact periodically with the crack tip of the middle crack. A model based on a variational approach analytically predicts the condition of propagation and geometrical features of three parallel cracks. The stability conditions and oscillating propagation are found numerically and the predictions are in favorable agreement with experiments. We found that the physical mechanism selecting the wavelength structure is a relaxation process in which the middle crack produces a regular oscillatory path.

AB - We report a new oscillatory propagation of cracks in thin films where three cracks interact mediated by two delamination fronts. Experimental observations indicate that delamination fronts joining the middle crack to the lateral crack tips swap contact periodically with the crack tip of the middle crack. A model based on a variational approach analytically predicts the condition of propagation and geometrical features of three parallel cracks. The stability conditions and oscillating propagation are found numerically and the predictions are in favorable agreement with experiments. We found that the physical mechanism selecting the wavelength structure is a relaxation process in which the middle crack produces a regular oscillatory path.

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DO - 10.1103/PhysRevLett.124.174102

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SN - 0031-9007

VL - 124

JO - Physical Review Letters

JF - Physical Review Letters

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Collaborative Oscillatory Fracture

Abstract

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