Self-replicating cracks: A collaborative fracture mode in thin films

Joël Marthelot; Benoît Roman; José Bico; Jérémie Teisseire; Davy Dalmas; Francisco Melo

doi:10.1103/PhysRevLett.113.085502

Self-replicating cracks: A collaborative fracture mode in thin films

Joël Marthelot
, Benoît Roman
, José Bico
, Jérémie Teisseire
, Davy Dalmas
, Francisco Melo

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

Abstract

Straight cracks are observed in thin coatings under residual tensile stress, resulting into the classical network pattern observed in china crockery, old paintings, or dry mud. Here, we present a novel fracture mechanism where delamination and propagation occur simultaneously, leading to the spontaneous self-replication of an initial template. Surprisingly, this mechanism is active below the standard critical tensile load for channel cracks and selects a robust interaction length scale on the order of 30 times the film thickness. Depending on triggering mechanisms, crescent alleys, spirals, or long bands are generated over a wide range of experimental parameters. We describe with a simple physical model, the selection of the fracture path and provide a configuration diagram displaying the different failure modes.

Original language	English
Article number	085502
Journal	Physical Review Letters
Volume	113
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevLett.113.085502
Publication status	Published - 20 Aug 2014
Externally published	Yes

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10.1103/PhysRevLett.113.085502

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title = "Self-replicating cracks: A collaborative fracture mode in thin films",

abstract = "Straight cracks are observed in thin coatings under residual tensile stress, resulting into the classical network pattern observed in china crockery, old paintings, or dry mud. Here, we present a novel fracture mechanism where delamination and propagation occur simultaneously, leading to the spontaneous self-replication of an initial template. Surprisingly, this mechanism is active below the standard critical tensile load for channel cracks and selects a robust interaction length scale on the order of 30 times the film thickness. Depending on triggering mechanisms, crescent alleys, spirals, or long bands are generated over a wide range of experimental parameters. We describe with a simple physical model, the selection of the fracture path and provide a configuration diagram displaying the different failure modes.",

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AU - Teisseire, Jérémie

AU - Dalmas, Davy

AU - Melo, Francisco

PY - 2014/8/20

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AB - Straight cracks are observed in thin coatings under residual tensile stress, resulting into the classical network pattern observed in china crockery, old paintings, or dry mud. Here, we present a novel fracture mechanism where delamination and propagation occur simultaneously, leading to the spontaneous self-replication of an initial template. Surprisingly, this mechanism is active below the standard critical tensile load for channel cracks and selects a robust interaction length scale on the order of 30 times the film thickness. Depending on triggering mechanisms, crescent alleys, spirals, or long bands are generated over a wide range of experimental parameters. We describe with a simple physical model, the selection of the fracture path and provide a configuration diagram displaying the different failure modes.

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Self-replicating cracks: A collaborative fracture mode in thin films

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