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A thermodynamic theory for dislocation cell formation and misorientation in metals

A thermodynamic theory for dislocation cell formation and misorientation in metals
A thermodynamic theory for dislocation cell formation and misorientation in metals

Expressions for obtaining the dislocation cell size and misorientation angle evolution as functions of strain, strain rate and temperature are presented. The basis of the theory is to express the cell formation energy as a set of dislocation partials, which is equated to the energy of the dislocation forest in the non-cellular material plus the dislocation slip energy to form cellular structures. The latter is expressed in terms of the statistical entropy for dislocation slip. The Young-Laplace equation is applied to obtain the cell misorientation angle at stages III and IV of deformation. This equation is also applied to obtain an expression for the dislocation density evolution at stage IV. The theory is applied to the deformation of Cu, Al and Ni, from low to high temperature conditions and at various strain rates, describing well the cell properties and the corresponding stress-strain curves.

Dislocation theory, Modelling, Plastic deformation, Statistical mechanics, Subgrain growth
1359-6454
4370-4378
Galindo-Nava, E. I.
55a2bf00-0903-414e-8ab6-e26d143a9af3
Rivera-Díaz-Del-Castillo, P. E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Galindo-Nava, E. I.
55a2bf00-0903-414e-8ab6-e26d143a9af3
Rivera-Díaz-Del-Castillo, P. E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2

Galindo-Nava, E. I. and Rivera-Díaz-Del-Castillo, P. E.J. (2012) A thermodynamic theory for dislocation cell formation and misorientation in metals. Acta Materialia, 60 (11), 4370-4378. (doi:10.1016/j.actamat.2012.05.003).

Record type: Article

Abstract

Expressions for obtaining the dislocation cell size and misorientation angle evolution as functions of strain, strain rate and temperature are presented. The basis of the theory is to express the cell formation energy as a set of dislocation partials, which is equated to the energy of the dislocation forest in the non-cellular material plus the dislocation slip energy to form cellular structures. The latter is expressed in terms of the statistical entropy for dislocation slip. The Young-Laplace equation is applied to obtain the cell misorientation angle at stages III and IV of deformation. This equation is also applied to obtain an expression for the dislocation density evolution at stage IV. The theory is applied to the deformation of Cu, Al and Ni, from low to high temperature conditions and at various strain rates, describing well the cell properties and the corresponding stress-strain curves.

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More information

Published date: June 2012
Keywords: Dislocation theory, Modelling, Plastic deformation, Statistical mechanics, Subgrain growth

Identifiers

Local EPrints ID: 492563
URI: http://eprints.soton.ac.uk/id/eprint/492563
DOI: doi:10.1016/j.actamat.2012.05.003
ISSN: 1359-6454
PURE UUID: f2814cc8-c44c-439f-a850-c21c394acda4
ORCID for P. E.J. Rivera-Díaz-Del-Castillo: ORCID iD orcid.org/0000-0002-0419-8347

Catalogue record

Date deposited: 05 Aug 2024 16:44
Last modified: 06 Aug 2024 02:04

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Contributors

Author: E. I. Galindo-Nava
Author: P. E.J. Rivera-Díaz-Del-Castillo ORCID iD

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