Nature Communications (Nov 2024)

Isotope-dependent site occupation of hydrogen in epitaxial titanium hydride nanofilms

  • T. Ozawa,
  • Y. Sugisawa,
  • Y. Komatsu,
  • R. Shimizu,
  • T. Hitosugi,
  • D. Sekiba,
  • K. Yamauchi,
  • I. Hamada,
  • K. Fukutani

DOI
https://doi.org/10.1038/s41467-024-53838-6
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 8

Abstract

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Abstract Hydrogen, the smallest and lightest element, readily permeates a variety of materials and modulates their physical properties. Identification of the hydrogen lattice location and its amount in crystals is key to understanding and controlling the hydrogen-induced properties. Combining nuclear reaction analysis (NRA) with the ion channeling technique, we experimentally determined the locations of H and D in epitaxial nanofilms of titanium hydrides from the analysis of the two-dimensional angular mappings of NRA yields. Here we show that 11 at% of H are located at the octahedral site with the remaining H atoms in the tetrahedral site. Density functional theory calculations revealed that the structures with the partial octahedral site occupation are stabilized by the Fermi level shift and Jahn-Teller effect induced by hydrogen. In contrast, D was found to solely occupy the tetrahedral site owing to the mass effect on the zero-point vibrational energy. These findings suggest that site occupation of hydrogen can be controlled by changing the isotope mixture ratio, which leads to promising manifestation of novel hydrogen-related phenomena.