Core structure, dislocation energy and Peierls stress for 1/3 〈1 1 2̄ 0〉 edge dislocations with (0 0 0 1) and {1 1̄ 0 0} slip planes in α-Zr

R. E. Voskoboinikov; Yu N. Osetsky; D. J. Bacon

doi:10.1016/j.msea.2005.03.089

Core structure, dislocation energy and Peierls stress for 1/3 〈1 1 2̄ 0〉 edge dislocations with (0 0 0 1) and {1 1̄ 0 0} slip planes in α-Zr

R. E. Voskoboinikov, Yu N. Osetsky, D. J. Bacon

Research output: Contribution to journal › Article › peer-review

19 Scopus citations

Abstract

Atomic-scale simulations of edge dislocations of the 1/3 〈1 1 2̄ 0〉 (0 0 0 1) and 1/3 〈1 1 2̄ 0〉 {1 1̄ 0 0} slip systems have been carried out using a Finnis-Sinclair-type interatomic potential for α-zirconium. The distribution of atomic displacements in the dislocation core shows that in this model the edge dislocation in the basal plane dissociates into two Shockley partials whereas the dislocation in the prism plane remains undissociated. The effective core radius and core energy are estimated, and dislocation response to increasing applied shear strain is investigated. The core properties and the critical stress for dislocation glide (Peierls stress) depend sensitively on whether the core extends or not.

Original language	English
Pages (from-to)	45-48
Number of pages	4
Journal	Materials Science and Engineering: A
Volume	400-401
Issue number	1-2 SUPPL.
DOIs	https://doi.org/10.1016/j.msea.2005.03.089
State	Published - Jul 25 2005

Funding

This research was supported by grant FIKS-CT-2001-00137 (‘SIRENA’) from the Council of the European Commission and by contract T27L92-F56398 with Electricité de France and by Division of Materials Science and Engineering, US Department of Energy, under contract DE-AC05-00OR22725 with UT-Battelle, LLC.

Keywords

Atomic-scale modelling
Dislocation core
Extended dislocation
Peierls stress
Stacking fault

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title = "Core structure, dislocation energy and Peierls stress for 1/3 〈1 1 {\=2} 0〉 edge dislocations with (0 0 0 1) and {1 {\=1} 0 0} slip planes in α-Zr",

abstract = "Atomic-scale simulations of edge dislocations of the 1/3 〈1 1 {\=2} 0〉 (0 0 0 1) and 1/3 〈1 1 {\=2} 0〉 {1 {\=1} 0 0} slip systems have been carried out using a Finnis-Sinclair-type interatomic potential for α-zirconium. The distribution of atomic displacements in the dislocation core shows that in this model the edge dislocation in the basal plane dissociates into two Shockley partials whereas the dislocation in the prism plane remains undissociated. The effective core radius and core energy are estimated, and dislocation response to increasing applied shear strain is investigated. The core properties and the critical stress for dislocation glide (Peierls stress) depend sensitively on whether the core extends or not.",

keywords = "Atomic-scale modelling, Dislocation core, Extended dislocation, Peierls stress, Stacking fault",

author = "Voskoboinikov, {R. E.} and Osetsky, {Yu N.} and Bacon, {D. J.}",

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language = "English",

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T1 - Core structure, dislocation energy and Peierls stress for 1/3 〈1 1 2̄ 0〉 edge dislocations with (0 0 0 1) and {1 1̄ 0 0} slip planes in α-Zr

AU - Voskoboinikov, R. E.

AU - Osetsky, Yu N.

AU - Bacon, D. J.

PY - 2005/7/25

Y1 - 2005/7/25

N2 - Atomic-scale simulations of edge dislocations of the 1/3 〈1 1 2̄ 0〉 (0 0 0 1) and 1/3 〈1 1 2̄ 0〉 {1 1̄ 0 0} slip systems have been carried out using a Finnis-Sinclair-type interatomic potential for α-zirconium. The distribution of atomic displacements in the dislocation core shows that in this model the edge dislocation in the basal plane dissociates into two Shockley partials whereas the dislocation in the prism plane remains undissociated. The effective core radius and core energy are estimated, and dislocation response to increasing applied shear strain is investigated. The core properties and the critical stress for dislocation glide (Peierls stress) depend sensitively on whether the core extends or not.

AB - Atomic-scale simulations of edge dislocations of the 1/3 〈1 1 2̄ 0〉 (0 0 0 1) and 1/3 〈1 1 2̄ 0〉 {1 1̄ 0 0} slip systems have been carried out using a Finnis-Sinclair-type interatomic potential for α-zirconium. The distribution of atomic displacements in the dislocation core shows that in this model the edge dislocation in the basal plane dissociates into two Shockley partials whereas the dislocation in the prism plane remains undissociated. The effective core radius and core energy are estimated, and dislocation response to increasing applied shear strain is investigated. The core properties and the critical stress for dislocation glide (Peierls stress) depend sensitively on whether the core extends or not.

KW - Atomic-scale modelling

KW - Dislocation core

KW - Extended dislocation

KW - Peierls stress

KW - Stacking fault

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DO - 10.1016/j.msea.2005.03.089

M3 - Article

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SN - 0921-5093

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JO - Materials Science and Engineering: A

JF - Materials Science and Engineering: A

IS - 1-2 SUPPL.

ER -

Core structure, dislocation energy and Peierls stress for 1/3 〈1 1 2̄ 0〉 edge dislocations with (0 0 0 1) and {1 1̄ 0 0} slip planes in α-Zr

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