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Bibliographic Details
Main Authors: Hudson, Thomas, Rindler, Filip, Rydell, Joshua
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.20294
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author Hudson, Thomas
Rindler, Filip
Rydell, Joshua
author_facet Hudson, Thomas
Rindler, Filip
Rydell, Joshua
contents This work introduces a simple quantitative model for the Frank--Read source, considered to be one of the most important micro-mechanical mechanisms of dislocation creation in crystalline materials. It has long been known that these sources create dislocations in a repetitive, oscillatory process, which is driven by an external shear force. Unlike the existing explanations in the literature, the model introduced in the present article is based on just a few simple physical principles, namely line tension and dislocation motion due to a single slip plane flow rule, together with a pinning constraint on the ends of the central dislocation line. A complete discretisation, including suitable re-meshing and ``topological cutting'' algorithms, is described and simulation results are discussed. Despite its conceptual simplicity, the model and discretisation described in the present work yield remarkably accurate predictions about the shape and properties of the Frank--Read source. In particular, it is shown that only one dimensionless parameter controls the dynamics of the Frank--Read source if one neglects crystal anisotropy. This allows to derive an emergent law about the length of dislocation line generated per shear energy.
format Preprint
id arxiv_https___arxiv_org_abs_2409_20294
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A quantitative model for the Frank-Read dislocation source based on pinned mean curvature flow
Hudson, Thomas
Rindler, Filip
Rydell, Joshua
Materials Science
Dynamical Systems
74H15
This work introduces a simple quantitative model for the Frank--Read source, considered to be one of the most important micro-mechanical mechanisms of dislocation creation in crystalline materials. It has long been known that these sources create dislocations in a repetitive, oscillatory process, which is driven by an external shear force. Unlike the existing explanations in the literature, the model introduced in the present article is based on just a few simple physical principles, namely line tension and dislocation motion due to a single slip plane flow rule, together with a pinning constraint on the ends of the central dislocation line. A complete discretisation, including suitable re-meshing and ``topological cutting'' algorithms, is described and simulation results are discussed. Despite its conceptual simplicity, the model and discretisation described in the present work yield remarkably accurate predictions about the shape and properties of the Frank--Read source. In particular, it is shown that only one dimensionless parameter controls the dynamics of the Frank--Read source if one neglects crystal anisotropy. This allows to derive an emergent law about the length of dislocation line generated per shear energy.
title A quantitative model for the Frank-Read dislocation source based on pinned mean curvature flow
topic Materials Science
Dynamical Systems
74H15
url https://arxiv.org/abs/2409.20294