Hydrogen-vacancy interaction in tungsten

J.R Fransens; M.S Abd El Keriem; F Pleiter

doi:10.1088/0953-8984/3/49/004

Hydrogen-vacancy interaction in tungsten

J.R Fransens^*, M.S Abd El Keriem , F Pleiter

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

49 Citations (Scopus)

Abstract

Hydrogen-vacancy interaction in tungsten was investigated by means of the perturbed angular correlation technique, using the isotope In-111 as a probe. Hydrogen trapping at an In-111-vacancy cluster manifests itself as a change of the local electric field gradient, which gives rise to an observable shift of the quadrupole frequency. The measurements show that a vacancy in tungsten can trap one or two hydrogen atoms at room temperature. The detrapping energies of the first and second hydrogen atom are 1.55(2) and 1.38(2) eV, respectively, while the detrapping energy of the next hydrogen atom is less than 1.1 eV. Substitutional In-111 atoms do not trap hydrogen at room temperature. At least two more hydrogen decorated defects were observed. Although their structures are not quite clear, they probably form from larger vacancy clusters and may contain a large amount of hydrogen. The dissociation energy of these bubble-like defects is 1.30(2) eV.

Original language	English
Pages (from-to)	9871-9886
Number of pages	16
Journal	Journal of Physics-Condensed Matter
Volume	3
Issue number	49
DOIs	https://doi.org/10.1088/0953-8984/3/49/004
Publication status	Published - 9-Dec-1991

Keywords

DEUTERIUM
METALS
MOLYBDENUM
IMPURITIES
LOCATION
CLUSTERS

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title = "Hydrogen-vacancy interaction in tungsten",

abstract = "Hydrogen-vacancy interaction in tungsten was investigated by means of the perturbed angular correlation technique, using the isotope In-111 as a probe. Hydrogen trapping at an In-111-vacancy cluster manifests itself as a change of the local electric field gradient, which gives rise to an observable shift of the quadrupole frequency. The measurements show that a vacancy in tungsten can trap one or two hydrogen atoms at room temperature. The detrapping energies of the first and second hydrogen atom are 1.55(2) and 1.38(2) eV, respectively, while the detrapping energy of the next hydrogen atom is less than 1.1 eV. Substitutional In-111 atoms do not trap hydrogen at room temperature. At least two more hydrogen decorated defects were observed. Although their structures are not quite clear, they probably form from larger vacancy clusters and may contain a large amount of hydrogen. The dissociation energy of these bubble-like defects is 1.30(2) eV.",

keywords = "DEUTERIUM, METALS, MOLYBDENUM, IMPURITIES, LOCATION, CLUSTERS",

author = "J.R Fransens and {Abd El Keriem}, M.S and F Pleiter",

year = "1991",

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doi = "10.1088/0953-8984/3/49/004",

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TY - JOUR

T1 - Hydrogen-vacancy interaction in tungsten

AU - Fransens, J.R

AU - Abd El Keriem , M.S

AU - Pleiter, F

PY - 1991/12/9

Y1 - 1991/12/9

N2 - Hydrogen-vacancy interaction in tungsten was investigated by means of the perturbed angular correlation technique, using the isotope In-111 as a probe. Hydrogen trapping at an In-111-vacancy cluster manifests itself as a change of the local electric field gradient, which gives rise to an observable shift of the quadrupole frequency. The measurements show that a vacancy in tungsten can trap one or two hydrogen atoms at room temperature. The detrapping energies of the first and second hydrogen atom are 1.55(2) and 1.38(2) eV, respectively, while the detrapping energy of the next hydrogen atom is less than 1.1 eV. Substitutional In-111 atoms do not trap hydrogen at room temperature. At least two more hydrogen decorated defects were observed. Although their structures are not quite clear, they probably form from larger vacancy clusters and may contain a large amount of hydrogen. The dissociation energy of these bubble-like defects is 1.30(2) eV.

AB - Hydrogen-vacancy interaction in tungsten was investigated by means of the perturbed angular correlation technique, using the isotope In-111 as a probe. Hydrogen trapping at an In-111-vacancy cluster manifests itself as a change of the local electric field gradient, which gives rise to an observable shift of the quadrupole frequency. The measurements show that a vacancy in tungsten can trap one or two hydrogen atoms at room temperature. The detrapping energies of the first and second hydrogen atom are 1.55(2) and 1.38(2) eV, respectively, while the detrapping energy of the next hydrogen atom is less than 1.1 eV. Substitutional In-111 atoms do not trap hydrogen at room temperature. At least two more hydrogen decorated defects were observed. Although their structures are not quite clear, they probably form from larger vacancy clusters and may contain a large amount of hydrogen. The dissociation energy of these bubble-like defects is 1.30(2) eV.

KW - DEUTERIUM

KW - METALS

KW - MOLYBDENUM

KW - IMPURITIES

KW - LOCATION

KW - CLUSTERS

U2 - 10.1088/0953-8984/3/49/004

DO - 10.1088/0953-8984/3/49/004

M3 - Article

SN - 0953-8984

VL - 3

SP - 9871

EP - 9886

JO - Journal of Physics-Condensed Matter

JF - Journal of Physics-Condensed Matter

IS - 49

ER -

Hydrogen-vacancy interaction in tungsten

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