Plastic behavior of fcc metals over a wide range of strain: macroscopic and microscopic descriptions and their relationship
Plastic behavior of fcc metals over a wide range of strain: macroscopic and microscopic descriptions and their relationship
The room temperature macroscopic and microscopic plastic behavior of four face-centered cubic metals (Al, Au, Cu and Ni) is investigated experimentally over a wide strain range, and theoretical modeling is used to simulate the established major micromechanisms describing the evolution of mobile and forest dislocations during plastic flow. It is shown that forest dislocations develop primarily due to interaction between mobile dislocations, while the contribution from forest–mobile interactions is only minor. The trapping of mobile dislocations and the annihilation of forest dislocations are both controlled by the same thermally activated dislocation motion. These observations permit a simplification of the theoretical model that leads to an analytical relationship for the evolution of the total dislocation density as a function of strain. From this analysis, correlations are drawn between the macroscopic parameters describing the stress–strain relationship and the fundamental characteristics of the microscopic processes
2385-2391
Csanádi, Tamas
ff199ebb-ba8a-44ff-bd61-c8c4c9378b73
Chinh, Nguyen Q.
8e075269-61a9-469c-8f71-3d52eb37dadc
Gubicza, Jeno
2a3c6ad7-cd7b-49d0-a0cc-1d307b51528c
Langdon, Terence G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
April 2011
Csanádi, Tamas
ff199ebb-ba8a-44ff-bd61-c8c4c9378b73
Chinh, Nguyen Q.
8e075269-61a9-469c-8f71-3d52eb37dadc
Gubicza, Jeno
2a3c6ad7-cd7b-49d0-a0cc-1d307b51528c
Langdon, Terence G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
Csanádi, Tamas, Chinh, Nguyen Q., Gubicza, Jeno and Langdon, Terence G.
(2011)
Plastic behavior of fcc metals over a wide range of strain: macroscopic and microscopic descriptions and their relationship.
Acta Materialia, 59 (6), .
(doi:10.1016/j.actamat.2010.12.034).
Abstract
The room temperature macroscopic and microscopic plastic behavior of four face-centered cubic metals (Al, Au, Cu and Ni) is investigated experimentally over a wide strain range, and theoretical modeling is used to simulate the established major micromechanisms describing the evolution of mobile and forest dislocations during plastic flow. It is shown that forest dislocations develop primarily due to interaction between mobile dislocations, while the contribution from forest–mobile interactions is only minor. The trapping of mobile dislocations and the annihilation of forest dislocations are both controlled by the same thermally activated dislocation motion. These observations permit a simplification of the theoretical model that leads to an analytical relationship for the evolution of the total dislocation density as a function of strain. From this analysis, correlations are drawn between the macroscopic parameters describing the stress–strain relationship and the fundamental characteristics of the microscopic processes
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Published date: April 2011
Organisations:
Engineering Mats & Surface Engineerg Gp
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Local EPrints ID: 190949
URI: http://eprints.soton.ac.uk/id/eprint/190949
ISSN: 1359-6454
PURE UUID: 53260032-3371-466b-bc86-a3f00b245139
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Date deposited: 16 Jun 2011 11:26
Last modified: 15 Mar 2024 03:13
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Author:
Tamas Csanádi
Author:
Nguyen Q. Chinh
Author:
Jeno Gubicza
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