Nanoscale-hydride formation at dislocations in palladium: Ab initio theory and incoherent inelastic neutron scattering measurements

(2) Department of Nuclear; (3) NIST Center for Neutron Research; Brent J. Heuser (2); Dallas R. Trinkle (1); Engineering; Hyunsu Ju (2); National Institute of Standards; Plasma; Radiological Engineering; Technology)

arxiv: 1104.3757 · v1 · pith:CEBUFIVGnew · submitted 2011-04-19 · ❄️ cond-mat.mtrl-sci · physics.comp-ph

Nanoscale-hydride formation at dislocations in palladium: Ab initio theory and incoherent inelastic neutron scattering measurements

Dallas R. Trinkle (1) , Hyunsu Ju (2) , Brent J. Heuser (2) , Terrence J. Udovic (3) ((1) Department of Materials Science , Engineering , University of Illinois , Urbana-Champaign , (2) Department of Nuclear

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Plasma Radiological Engineering (3) NIST Center for Neutron Research National Institute of Standards Technology)

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classification ❄️ cond-mat.mtrl-sci physics.comp-ph

keywords hydrideshydrogentemperaturedislocationdislocationsformincoherentinelastic

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Hydrogen arranges at dislocations in palladium to form nanoscale hydrides, changing the vibrational spectra. An ab initio hydrogen potential energy model versus Pd neighbor distances allows us to predict the vibrational excitations for H from absolute zero up to room temperature adjacent to a partial dislocation and with strain. Using the equilibrium distribution of hydrogen with temperature, we predict excitation spectra to explain new incoherent inelastic neutron-scattering measurements. At 0K, dislocation cores trap H to form nanometer-sized hydrides, while increased temperature dissolves the hydrides and disperses H throughout bulk Pd.

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Nanoscale-hydride formation at dislocations in palladium: Ab initio theory and incoherent inelastic neutron scattering measurements

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