Hydrogen-induced plasticity in nanoporous palladium

Hydrogen-induced plasticity in nanoporous palladium

The mechanical strain response of nanoporous palladium (npPd) upon electrochemical hydrogenation using an in situ dilatometric technique is investigated. NpPd with an average ligament diameter of approximately 20 nm is produced via electrochemical dealloying. A hydrogen-induced phase transition from...

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Main Authors: Markus Gößler, Eva-Maria Steyskal, Markus Stütz, Norbert Enzinger, Roland Würschum
Format: Article
Language:English
Published: Beilstein-Institut 2018-12-01
Series:Beilstein Journal of Nanotechnology
Subjects:
electrochemistry
hydride formation
in situ dilatometry
internal-stress plasticity
nanoporous palladium
Online Access:https://doi.org/10.3762/bjnano.9.280
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spelling doaj-b5e1b40323884c798a64edd6e4a4bf1f2020-11-24T21:47:06ZengBeilstein-InstitutBeilstein Journal of Nanotechnology2190-42862018-12-01913013302410.3762/bjnano.9.2802190-4286-9-280Hydrogen-induced plasticity in nanoporous palladiumMarkus Gößler0Eva-Maria Steyskal1Markus Stütz2Norbert Enzinger3Roland Würschum4Institute of Materials Physics, Graz University of Technology, Petersgasse 16, A-8010 Graz, AustriaInstitute of Materials Physics, Graz University of Technology, Petersgasse 16, A-8010 Graz, AustriaInstitute of Materials Science, Joining and Forming, Graz University of Technology, Kopernikusgasse 24/I, A-8010 Graz, AustriaInstitute of Materials Science, Joining and Forming, Graz University of Technology, Kopernikusgasse 24/I, A-8010 Graz, AustriaInstitute of Materials Physics, Graz University of Technology, Petersgasse 16, A-8010 Graz, AustriaThe mechanical strain response of nanoporous palladium (npPd) upon electrochemical hydrogenation using an in situ dilatometric technique is investigated. NpPd with an average ligament diameter of approximately 20 nm is produced via electrochemical dealloying. A hydrogen-induced phase transition from PdHβ to PdHα is found to enable internal-stress plasticity (or transformation-mismatch plasticity) in nanoporous palladium, which leads to exceptionally high strains without fracture as a result of external forces. The high surface stress in the nanoporous structure in combination with the internal-stress plasticity mechanism leads to a peculiar strain response upon hydrogen sorption and desorption. Critical potentials for the formation of PdHα and PdHβ in npPd are determined. The theoretical concepts to assess the plastic strain response of nanoporous samples are elucidated, taking into account characteristics of structure and deformation mechanism.https://doi.org/10.3762/bjnano.9.280electrochemistryhydride formationin situ dilatometryinternal-stress plasticitynanoporous palladium
collection DOAJ
language English
format Article
sources DOAJ
author Markus Gößler
Eva-Maria Steyskal
Markus Stütz
Norbert Enzinger
Roland Würschum
spellingShingle Markus Gößler
Eva-Maria Steyskal
Markus Stütz
Norbert Enzinger
Roland Würschum
Hydrogen-induced plasticity in nanoporous palladium
Beilstein Journal of Nanotechnology
electrochemistry
hydride formation
in situ dilatometry
internal-stress plasticity
nanoporous palladium
author_facet Markus Gößler
Eva-Maria Steyskal
Markus Stütz
Norbert Enzinger
Roland Würschum
author_sort Markus Gößler
title Hydrogen-induced plasticity in nanoporous palladium
title_short Hydrogen-induced plasticity in nanoporous palladium
title_full Hydrogen-induced plasticity in nanoporous palladium
title_fullStr Hydrogen-induced plasticity in nanoporous palladium
title_full_unstemmed Hydrogen-induced plasticity in nanoporous palladium
title_sort hydrogen-induced plasticity in nanoporous palladium
publisher Beilstein-Institut
series Beilstein Journal of Nanotechnology
issn 2190-4286
publishDate 2018-12-01
description The mechanical strain response of nanoporous palladium (npPd) upon electrochemical hydrogenation using an in situ dilatometric technique is investigated. NpPd with an average ligament diameter of approximately 20 nm is produced via electrochemical dealloying. A hydrogen-induced phase transition from PdHβ to PdHα is found to enable internal-stress plasticity (or transformation-mismatch plasticity) in nanoporous palladium, which leads to exceptionally high strains without fracture as a result of external forces. The high surface stress in the nanoporous structure in combination with the internal-stress plasticity mechanism leads to a peculiar strain response upon hydrogen sorption and desorption. Critical potentials for the formation of PdHα and PdHβ in npPd are determined. The theoretical concepts to assess the plastic strain response of nanoporous samples are elucidated, taking into account characteristics of structure and deformation mechanism.
topic electrochemistry
hydride formation
in situ dilatometry
internal-stress plasticity
nanoporous palladium
url https://doi.org/10.3762/bjnano.9.280
work_keys_str_mv AT markusgoßler hydrogeninducedplasticityinnanoporouspalladium
AT evamariasteyskal hydrogeninducedplasticityinnanoporouspalladium
AT markusstutz hydrogeninducedplasticityinnanoporouspalladium
AT norbertenzinger hydrogeninducedplasticityinnanoporouspalladium
AT rolandwurschum hydrogeninducedplasticityinnanoporouspalladium
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