Unveiling subsurface hydrogen-bond structure of hexagonal water ice

Yuji Otsuki; Toshiki Sugimoto; Tatsuya Ishiyama; Akihiro Morita; Kazuya Watanabe; Yoshiyasu Matsumoto

doi:10.1103/PhysRevB.96.115405

Unveiling subsurface hydrogen-bond structure of hexagonal water ice

Yuji Otsuki, Toshiki Sugimoto, Tatsuya Ishiyama, Akihiro Morita, Kazuya Watanabe, Yoshiyasu Matsumoto

Applied Chemistry

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

40 Scopus citations

Abstract

The phase-resolved sum-frequency-generation (SFG) spectrum for the basal face of hexagonal ice is reported and is interpreted by molecular dynamics simulations combined with ab initio quantum calculations. Here, we demonstrate that the line shape of the SFG spectra of isotope-diluted OH chromophores is a sensitive indicator of structural rumpling uniquely emerging at the subsurface of hexagonal ice. In the outermost subsurface between the first (B1) and second (B2) bilayer, the hydrogen bond of OB1-H"OB2 is weaker than that of OB1"H-OB2. This implies that subsurface O-O distance is laterally altered, depending on the direction of O-H bond along the surface normal: H-up or H-down, which is in stark contrast to bulk hydrogen bonds. This new finding uncovers how water molecules undercoordinated at the topmost surface influence on the subsurface structural rumpling associated with orientational frustration inherent in water ice.

Original language	English
Article number	115405
Journal	Physical Review B
Volume	96
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevB.96.115405
State	Published - 2017/09/05

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.96.115405

Cite this

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title = "Unveiling subsurface hydrogen-bond structure of hexagonal water ice",

abstract = "The phase-resolved sum-frequency-generation (SFG) spectrum for the basal face of hexagonal ice is reported and is interpreted by molecular dynamics simulations combined with ab initio quantum calculations. Here, we demonstrate that the line shape of the SFG spectra of isotope-diluted OH chromophores is a sensitive indicator of structural rumpling uniquely emerging at the subsurface of hexagonal ice. In the outermost subsurface between the first (B1) and second (B2) bilayer, the hydrogen bond of OB1-H{"}OB2 is weaker than that of OB1{"}H-OB2. This implies that subsurface O-O distance is laterally altered, depending on the direction of O-H bond along the surface normal: H-up or H-down, which is in stark contrast to bulk hydrogen bonds. This new finding uncovers how water molecules undercoordinated at the topmost surface influence on the subsurface structural rumpling associated with orientational frustration inherent in water ice.",

author = "Yuji Otsuki and Toshiki Sugimoto and Tatsuya Ishiyama and Akihiro Morita and Kazuya Watanabe and Yoshiyasu Matsumoto",

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AU - Otsuki, Yuji

AU - Sugimoto, Toshiki

AU - Ishiyama, Tatsuya

AU - Morita, Akihiro

AU - Watanabe, Kazuya

AU - Matsumoto, Yoshiyasu

PY - 2017/9/5

Y1 - 2017/9/5

N2 - The phase-resolved sum-frequency-generation (SFG) spectrum for the basal face of hexagonal ice is reported and is interpreted by molecular dynamics simulations combined with ab initio quantum calculations. Here, we demonstrate that the line shape of the SFG spectra of isotope-diluted OH chromophores is a sensitive indicator of structural rumpling uniquely emerging at the subsurface of hexagonal ice. In the outermost subsurface between the first (B1) and second (B2) bilayer, the hydrogen bond of OB1-H"OB2 is weaker than that of OB1"H-OB2. This implies that subsurface O-O distance is laterally altered, depending on the direction of O-H bond along the surface normal: H-up or H-down, which is in stark contrast to bulk hydrogen bonds. This new finding uncovers how water molecules undercoordinated at the topmost surface influence on the subsurface structural rumpling associated with orientational frustration inherent in water ice.

AB - The phase-resolved sum-frequency-generation (SFG) spectrum for the basal face of hexagonal ice is reported and is interpreted by molecular dynamics simulations combined with ab initio quantum calculations. Here, we demonstrate that the line shape of the SFG spectra of isotope-diluted OH chromophores is a sensitive indicator of structural rumpling uniquely emerging at the subsurface of hexagonal ice. In the outermost subsurface between the first (B1) and second (B2) bilayer, the hydrogen bond of OB1-H"OB2 is weaker than that of OB1"H-OB2. This implies that subsurface O-O distance is laterally altered, depending on the direction of O-H bond along the surface normal: H-up or H-down, which is in stark contrast to bulk hydrogen bonds. This new finding uncovers how water molecules undercoordinated at the topmost surface influence on the subsurface structural rumpling associated with orientational frustration inherent in water ice.

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Unveiling subsurface hydrogen-bond structure of hexagonal water ice

Abstract

ASJC Scopus subject areas

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