Creep Deformation by Dislocation Movement in Waspaloy

Whittaker, Mark; Harrison, Will; Deen, Christopher; Rae, Cathie; Williams, Steve

doi:10.3390/ma10010061

Journal article 1626 views 425 downloads

Creep Deformation by Dislocation Movement in Waspaloy

Mark Whittaker

, Will Harrison

, Christopher Deen, Cathie Rae, Steve Williams

Materials, Volume: 10, Issue: 1, Start page: 61

Swansea University Authors: Mark Whittaker , Will Harrison

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DOI (Published version): 10.3390/ma10010061

Abstract

Creep tests of the polycrystalline nickel alloy Waspaloy have been conducted at Swansea University, for varying stress conditions at 700 ◦C. Investigation through use of Transmission Electron Microscopy at Cambridge University has examined the dislocation networks formed under these conditions, with...

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Published in:	Materials
ISSN:	1996-1944
Published:	2017
Online Access:	Check full text
URI:	https://cronfa.swan.ac.uk/Record/cronfa31621

first_indexed	2017-01-12T14:43:43Z
last_indexed	2020-07-16T18:48:13Z
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spelling	2020-07-16T14:08:46.5117661 v2 31621 2017-01-12 Creep Deformation by Dislocation Movement in Waspaloy a146c6d442cb2c466d096179f9ac97ca 0000-0002-5854-0726 Mark Whittaker Mark Whittaker true false dae59f76fa4f63123aa028abfcd2b07a 0000-0002-0380-7075 Will Harrison Will Harrison true false 2017-01-12 EAAS Creep tests of the polycrystalline nickel alloy Waspaloy have been conducted at Swansea University, for varying stress conditions at 700 ◦C. Investigation through use of Transmission Electron Microscopy at Cambridge University has examined the dislocation networks formed under these conditions, with particular attention paid to comparing tests performed above and below the yield stress. This paper highlights how the dislocation structures vary throughout creep and proposes a dislocation mechanism theory for creep in Waspaloy. Activation energies are calculated through approaches developed in the use of the recently formulated Wilshire Equations, and are found to differ above and below the yield stress. Low activation energies are found to be related to dislocation interaction with γ 0 precipitates below the yield stress. However, significantly increased dislocation densities at stresses above yield cause an increase in the activation energy values as forest hardening becomes the primary mechanism controlling dislocation movement. It is proposed that the activation energy change is related to the stress increment provided by work hardening, as can be observed from Ti, Ni and steel results. Journal Article Materials 10 1 61 1996-1944 12 1 2017 2017-01-12 10.3390/ma10010061 COLLEGE NANME Engineering and Applied Sciences School COLLEGE CODE EAAS Swansea University 2020-07-16T14:08:46.5117661 2017-01-12T11:06:02.9733738 Faculty of Science and Engineering School of Engineering and Applied Sciences - Materials Science and Engineering Mark Whittaker 0000-0002-5854-0726 1 Will Harrison 0000-0002-0380-7075 2 Christopher Deen 3 Cathie Rae 4 Steve Williams 5 0031621-12012017110805.pdf whittaker2017.pdf 2017-01-12T11:08:05.3400000 Output 10600014 application/pdf Version of Record true 2017-01-12T00:00:00.0000000 This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited true https://creativecommons.org/licenses/by/4.0/
title	Creep Deformation by Dislocation Movement in Waspaloy
spellingShingle	Creep Deformation by Dislocation Movement in Waspaloy Mark Whittaker Will Harrison
title_short	Creep Deformation by Dislocation Movement in Waspaloy
title_full	Creep Deformation by Dislocation Movement in Waspaloy
title_fullStr	Creep Deformation by Dislocation Movement in Waspaloy
title_full_unstemmed	Creep Deformation by Dislocation Movement in Waspaloy
title_sort	Creep Deformation by Dislocation Movement in Waspaloy
author_id_str_mv	a146c6d442cb2c466d096179f9ac97ca dae59f76fa4f63123aa028abfcd2b07a
author_id_fullname_str_mv	a146c6d442cb2c466d096179f9ac97ca_*_Mark Whittaker dae59f76fa4f63123aa028abfcd2b07a_*_Will Harrison
author	Mark Whittaker Will Harrison
author2	Mark Whittaker Will Harrison Christopher Deen Cathie Rae Steve Williams
format	Journal article
container_title	Materials
container_volume	10
container_issue	1
container_start_page	61
publishDate	2017
institution	Swansea University
issn	1996-1944
doi_str_mv	10.3390/ma10010061
college_str	Faculty of Science and Engineering
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hierarchy_top_title	Faculty of Science and Engineering
hierarchy_parent_id	facultyofscienceandengineering
hierarchy_parent_title	Faculty of Science and Engineering
department_str	School of Engineering and Applied Sciences - Materials Science and Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Materials Science and Engineering
document_store_str	1
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description	Creep tests of the polycrystalline nickel alloy Waspaloy have been conducted at Swansea University, for varying stress conditions at 700 ◦C. Investigation through use of Transmission Electron Microscopy at Cambridge University has examined the dislocation networks formed under these conditions, with particular attention paid to comparing tests performed above and below the yield stress. This paper highlights how the dislocation structures vary throughout creep and proposes a dislocation mechanism theory for creep in Waspaloy. Activation energies are calculated through approaches developed in the use of the recently formulated Wilshire Equations, and are found to differ above and below the yield stress. Low activation energies are found to be related to dislocation interaction with γ 0 precipitates below the yield stress. However, significantly increased dislocation densities at stresses above yield cause an increase in the activation energy values as forest hardening becomes the primary mechanism controlling dislocation movement. It is proposed that the activation energy change is related to the stress increment provided by work hardening, as can be observed from Ti, Ni and steel results.
published_date	2017-01-12T19:09:55Z
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score	11.047609

Creep Deformation by Dislocation Movement in Waspaloy

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