Crystals (Jun 2021)

Studies of Hydrogen Bond Vibrations of Hydrogen-Disordered Ice Ic

  • Xu-Hao Yu,
  • Xiao-Ling Qin,
  • Xiao-Tong Dong,
  • Jing-Wen Cao,
  • Xu-Liang Zhu,
  • Hao-Cheng Wang,
  • Yan-Ju Sun,
  • Zi-Xun Xu,
  • Peng Zhang

DOI
https://doi.org/10.3390/cryst11060668
Journal volume & issue
Vol. 11, no. 6
p. 668

Abstract

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The hydrogen-disordered structure of ice, Ic, makes it difficult to analyze the vibrational normal modes in the far-infrared region (i.e., the molecular translation band). To clarify the origin of the energy-splitting of hydrogen bond vibrations in this area, a 64-molecule supercell was constructed and calculated using first-principles density functional theory. The results were in good agreement with inelastic neutron scattering experiments and our previous study of a hydrogen-ordered ice Ic model. Assisted by analytic equations, we concluded that the origin of the two hydrogen bond peaks in real ice Ic is consistent with that of hydrogen-ordered ice Ic: the peaks originate from two kinds of normal mode vibration. We categorize the four peaks in the far-infrared region recorded from inelastic neutron scattering experiments as the acoustic peak, the superposition peak, the two-hydrogen bond peak and the four-hydrogen bond peak. We conclude that the existence of two intrinsic hydrogen bond vibration modes represents a general rule among the ice family, except ice X.

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