Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue

Nanostructured metals with maximal grain or twin sizes of less than 100 nm have advanced properties like increased strength.As beneficial as these microstructures can be for the strength of materials, they are not infinitely stable. During mechanical loading these metals tend to coarsen and lose the...

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Auteur principal: Funk, Matthias Friedrich
Format: Online
Langue:anglais
Publié: KIT Scientific Publishing 2021
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Accès en ligne:34506
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author Funk, Matthias Friedrich
author_browse Funk, Matthias Friedrich
author_facet Funk, Matthias Friedrich
author_sort Funk, Matthias Friedrich
collection Directory of Open Access Books
description Nanostructured metals with maximal grain or twin sizes of less than 100 nm have advanced properties like increased strength.As beneficial as these microstructures can be for the strength of materials, they are not infinitely stable. During mechanical loading these metals tend to coarsen and lose their beneficial structure. Besides electron microscopic analysis of fatigued samples, in situ cycling tests were conducted in order to observe structural degradation during mechanical loading.
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id doab-20.500.12854ir-53444
institution Directory of Open Access Books
language eng
publishDate 2021
publishDateRange 2021
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publisherStr KIT Scientific Publishing
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spelling doab-20.500.12854ir-534442024-04-09T23:16:26Z Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue Funk, Matthias Friedrich T1-995 fatigue nanostructured metals electron microscopy in situ thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues Nanostructured metals with maximal grain or twin sizes of less than 100 nm have advanced properties like increased strength.As beneficial as these microstructures can be for the strength of materials, they are not infinitely stable. During mechanical loading these metals tend to coarsen and lose their beneficial structure. Besides electron microscopic analysis of fatigued samples, in situ cycling tests were conducted in order to observe structural degradation during mechanical loading. 2021-02-11T19:36:06Z 2021-02-11T19:36:06Z 2019-07-30 20:01:58 2012 book 34506 21929963 9783866449183 https://directory.doabooks.org/handle/20.500.12854/53444 eng Schriftenreihe des Instituts für Angewandte Materialien, Karlsruher Institut für Technologie image/jpeg Attribution-NonCommercial-NoDerivatives 4.0 International https://www.ksp.kit.edu/9783866449183 KIT Scientific Publishing 10.5445/KSP/1000030072 10.5445/KSP/1000030072 68fffc18-8f7b-44fa-ac7e-0b7d7d979bd2 9783866449183 XIV, 190 p. open access
spellingShingle T1-995
fatigue
nanostructured metals
electron microscopy
in situ
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
Funk, Matthias Friedrich
Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue
title Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue
title_full Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue
title_fullStr Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue
title_full_unstemmed Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue
title_short Microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue
title_sort microstructural stability of nanostructured fcc metals during cyclic deformation and fatigue
topic T1-995
fatigue
nanostructured metals
electron microscopy
in situ
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
topic_facet T1-995
fatigue
nanostructured metals
electron microscopy
in situ
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues
url 34506
work_keys_str_mv AT funkmatthiasfriedrich microstructuralstabilityofnanostructuredfccmetalsduringcyclicdeformationandfatigue