Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel

Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel

304LN stainless was subjected to multiaxial loading employing different waveforms and load paths. The grain boundary misorientation profile so obtained post deformation was compared across loading conditions. It was found that the uniaxial and proportional conditions of loading result in more of twi...

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Main Authors: Dey Rima, Tarafder Soumitra, Sivaprasad S
Format: Article
Language:English
Published: EDP Sciences 2019-01-01
Series:MATEC Web of Conferences
Online Access:https://www.matec-conferences.org/articles/matecconf/pdf/2019/49/matecconf_icmff1218_08007.pdf
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spelling doaj-8155a939e94d498cb742f4bce580f3c22021-02-02T06:42:06ZengEDP SciencesMATEC Web of Conferences2261-236X2019-01-013000800710.1051/matecconf/201930008007matecconf_icmff1218_08007Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steelDey Rima0Tarafder Soumitra1Sivaprasad S2Academy of scientific and innovative research (AcSIR)CSIR-National metallurgical laboratoryCSIR-National metallurgical laboratory304LN stainless was subjected to multiaxial loading employing different waveforms and load paths. The grain boundary misorientation profile so obtained post deformation was compared across loading conditions. It was found that the uniaxial and proportional conditions of loading result in more of twins, contrary to non-proportional loading conditions that resulted in substantially higher low angle grain boundaries. Also, under non-proportional loading the trapezoidal load path resulted in remarkably altered distribution of the grain boundaries compared to its contemporaries. Predominant martensitic transformation was found to be dominant mechanism of deformation for trapezoidal loading that also contributed to the altered misorientation profile.https://www.matec-conferences.org/articles/matecconf/pdf/2019/49/matecconf_icmff1218_08007.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Dey Rima
Tarafder Soumitra
Sivaprasad S
spellingShingle Dey Rima
Tarafder Soumitra
Sivaprasad S
Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel
MATEC Web of Conferences
author_facet Dey Rima
Tarafder Soumitra
Sivaprasad S
author_sort Dey Rima
title Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel
title_short Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel
title_full Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel
title_fullStr Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel
title_full_unstemmed Influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel
title_sort influence of multiaxial cyclic plastic loading on grain boundary misorientation profile in austenitic stainless steel
publisher EDP Sciences
series MATEC Web of Conferences
issn 2261-236X
publishDate 2019-01-01
description 304LN stainless was subjected to multiaxial loading employing different waveforms and load paths. The grain boundary misorientation profile so obtained post deformation was compared across loading conditions. It was found that the uniaxial and proportional conditions of loading result in more of twins, contrary to non-proportional loading conditions that resulted in substantially higher low angle grain boundaries. Also, under non-proportional loading the trapezoidal load path resulted in remarkably altered distribution of the grain boundaries compared to its contemporaries. Predominant martensitic transformation was found to be dominant mechanism of deformation for trapezoidal loading that also contributed to the altered misorientation profile.
url https://www.matec-conferences.org/articles/matecconf/pdf/2019/49/matecconf_icmff1218_08007.pdf
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AT tarafdersoumitra influenceofmultiaxialcyclicplasticloadingongrainboundarymisorientationprofileinausteniticstainlesssteel
AT sivaprasads influenceofmultiaxialcyclicplasticloadingongrainboundarymisorientationprofileinausteniticstainlesssteel
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