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Auteur principal: Brantut, Nicolas
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2403.07583
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author Brantut, Nicolas
author_facet Brantut, Nicolas
contents Strain hardening is a key feature observed in many rocks deformed in the so-called ``semi-brittle'' regime, where both crystal plastic and brittle deformation mechanisms operate. Dislocation storage has long been recognised as a major process leading to strain hardening. Here, we suggest that tensile microcracks may be viewed as dislocation sinks, by offering internal free surfaces where dislocations can escape individual crystals within an aggregate. Strain hardening is modelled with a conventional approach, combining Taylor's equation relating stress to dislocation density, and a dislocation density evolution law based on dislocation mean-free path and dynamic recovery. The initiation of microcracks is modelled as a function dislocation density, assuming dislocation pile-ups at grain boundaries. Microcrack growth is modelled using linear elastic fracture mechanics. The model captures important qualitative features observed in calcite marble deformation experiments: pressure-dependency of strength in the ductile regime, and a reduction in hardening linked to an increase in crack growth with decreasing confining pressure. Grain-size dependency of strength and hardening is also captured but requires significant toughening (or limitation to crack growth) at small grain sizes. The model can be improved significantly once detailed, systematic microstructural observations become available.
format Preprint
id arxiv_https___arxiv_org_abs_2403_07583
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Semi-brittle flow of rocks: Cracks, dislocations and strain hardening
Brantut, Nicolas
Geophysics
Strain hardening is a key feature observed in many rocks deformed in the so-called ``semi-brittle'' regime, where both crystal plastic and brittle deformation mechanisms operate. Dislocation storage has long been recognised as a major process leading to strain hardening. Here, we suggest that tensile microcracks may be viewed as dislocation sinks, by offering internal free surfaces where dislocations can escape individual crystals within an aggregate. Strain hardening is modelled with a conventional approach, combining Taylor's equation relating stress to dislocation density, and a dislocation density evolution law based on dislocation mean-free path and dynamic recovery. The initiation of microcracks is modelled as a function dislocation density, assuming dislocation pile-ups at grain boundaries. Microcrack growth is modelled using linear elastic fracture mechanics. The model captures important qualitative features observed in calcite marble deformation experiments: pressure-dependency of strength in the ductile regime, and a reduction in hardening linked to an increase in crack growth with decreasing confining pressure. Grain-size dependency of strength and hardening is also captured but requires significant toughening (or limitation to crack growth) at small grain sizes. The model can be improved significantly once detailed, systematic microstructural observations become available.
title Semi-brittle flow of rocks: Cracks, dislocations and strain hardening
topic Geophysics
url https://arxiv.org/abs/2403.07583