Dislocation annihilation in plastic deformation: I. multiscale irreversible thermodynamics
Dislocation annihilation in plastic deformation: I. multiscale irreversible thermodynamics
Irreversible thermodynamics is employed as a framework to describe plastic deformation in pure metals and alloys. Expressions to describe saturation stress in single crystals and nanocrystals are employed over wide ranges of temperature, strain rate and grain size. The importance of the roles played by vacancy self-diffusion in dislocation climb and in plasticity is shown. Equations to describe the stress-strain response of single crystals and ultrafine-grained metals are derived. The activation energy for dislocation annihilation plays a central role in the mechanical response of the systems. Succinct formulations for predicting hot deformation behaviour and relaxation of industrial alloys are presented; the influence of composition in the activation energy for dislocation annihilation is shown. All formulations describing stress-strain relationships can be reduced to Kocks-Mecking classical formulation, but incorporating grain size and compositional effects. The importance of the recovery term in such formulation is established, as well as the need to obtain it employing more fundamental approaches.
Modelling, Plastic deformation, Statistical mechanics, Theory, Thermodynamics
2606-2614
Rivera-Díaz-Del-Castillo, P.E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Huang, M.
af840a99-2fc4-4428-8b90-346a90ded789
April 2012
Rivera-Díaz-Del-Castillo, P.E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Huang, M.
af840a99-2fc4-4428-8b90-346a90ded789
Rivera-Díaz-Del-Castillo, P.E.J. and Huang, M.
(2012)
Dislocation annihilation in plastic deformation: I. multiscale irreversible thermodynamics.
Acta Materialia, 60 (6-7), .
(doi:10.1016/j.actamat.2012.01.027).
Abstract
Irreversible thermodynamics is employed as a framework to describe plastic deformation in pure metals and alloys. Expressions to describe saturation stress in single crystals and nanocrystals are employed over wide ranges of temperature, strain rate and grain size. The importance of the roles played by vacancy self-diffusion in dislocation climb and in plasticity is shown. Equations to describe the stress-strain response of single crystals and ultrafine-grained metals are derived. The activation energy for dislocation annihilation plays a central role in the mechanical response of the systems. Succinct formulations for predicting hot deformation behaviour and relaxation of industrial alloys are presented; the influence of composition in the activation energy for dislocation annihilation is shown. All formulations describing stress-strain relationships can be reduced to Kocks-Mecking classical formulation, but incorporating grain size and compositional effects. The importance of the recovery term in such formulation is established, as well as the need to obtain it employing more fundamental approaches.
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e-pub ahead of print date: 3 March 2012
Published date: April 2012
Keywords:
Modelling, Plastic deformation, Statistical mechanics, Theory, Thermodynamics
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Local EPrints ID: 492723
URI: http://eprints.soton.ac.uk/id/eprint/492723
ISSN: 1359-6454
PURE UUID: 878820d8-05b2-4da0-8c94-e523c3c55c97
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Date deposited: 13 Aug 2024 16:33
Last modified: 14 Aug 2024 02:07
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Author:
P.E.J. Rivera-Díaz-Del-Castillo
Author:
M. Huang
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