Phase diagram of ice polymorphs under negative pressure considering the limits of mechanical stability

Takahiro Matsui; Takuma Yagasaki; Masakazu Matsumoto; Hideki Tanaka

doi:10.1063/1.5083021

Phase diagram of ice polymorphs under negative pressure considering the limits of mechanical stability

Takahiro Matsui, Takuma Yagasaki, Masakazu Matsumoto, Hideki Tanaka

Research Institute for Interdisciplinary Science

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

16 Citations (Scopus)

Abstract

Thermodynamic and mechanical stabilities of various ultralow-density ices are examined using computer simulations to construct the phase diagram of ice under negative pressure. Some ultralow-density ices, which were predicted to be thermodynamically metastable under negative pressures on the basis of the quasi-harmonic approximation, can exist only in a narrow pressure range at very low temperatures because they are mechanically fragile due to the large distortion in the hydrogen bonding network. By contrast, relatively dense ices such as ice Ih and ice XVI withstand large negative pressure. Consequently, various ices appear one after another in the phase diagram. The phase diagram of ice under negative pressure exhibits a different complexity from that of positive pressure because of the mechanical instability.

Original language	English
Article number	041102
Journal	Journal of Chemical Physics
Volume	150
Issue number	4
DOIs	https://doi.org/10.1063/1.5083021
Publication status	Published - Jan 28 2019

ASJC Scopus subject areas

Physics and Astronomy(all)
Physical and Theoretical Chemistry

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10.1063/1.5083021

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abstract = "Thermodynamic and mechanical stabilities of various ultralow-density ices are examined using computer simulations to construct the phase diagram of ice under negative pressure. Some ultralow-density ices, which were predicted to be thermodynamically metastable under negative pressures on the basis of the quasi-harmonic approximation, can exist only in a narrow pressure range at very low temperatures because they are mechanically fragile due to the large distortion in the hydrogen bonding network. By contrast, relatively dense ices such as ice Ih and ice XVI withstand large negative pressure. Consequently, various ices appear one after another in the phase diagram. The phase diagram of ice under negative pressure exhibits a different complexity from that of positive pressure because of the mechanical instability.",

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AU - Matsui, Takahiro

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AU - Tanaka, Hideki

N1 - Funding Information: This work was supported by a grant from MORINO FOUNDATION FOR MOLECULAR SCIENCE and JSPS KAKENHI Grant No. 16K05658 and MEXT as “Priority Issue on Post-Kcomputer” (Development of new fundamental technologies for high-efficiency energy creation, conversion/storage and use). Publisher Copyright: © 2019 Author(s).

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N2 - Thermodynamic and mechanical stabilities of various ultralow-density ices are examined using computer simulations to construct the phase diagram of ice under negative pressure. Some ultralow-density ices, which were predicted to be thermodynamically metastable under negative pressures on the basis of the quasi-harmonic approximation, can exist only in a narrow pressure range at very low temperatures because they are mechanically fragile due to the large distortion in the hydrogen bonding network. By contrast, relatively dense ices such as ice Ih and ice XVI withstand large negative pressure. Consequently, various ices appear one after another in the phase diagram. The phase diagram of ice under negative pressure exhibits a different complexity from that of positive pressure because of the mechanical instability.

AB - Thermodynamic and mechanical stabilities of various ultralow-density ices are examined using computer simulations to construct the phase diagram of ice under negative pressure. Some ultralow-density ices, which were predicted to be thermodynamically metastable under negative pressures on the basis of the quasi-harmonic approximation, can exist only in a narrow pressure range at very low temperatures because they are mechanically fragile due to the large distortion in the hydrogen bonding network. By contrast, relatively dense ices such as ice Ih and ice XVI withstand large negative pressure. Consequently, various ices appear one after another in the phase diagram. The phase diagram of ice under negative pressure exhibits a different complexity from that of positive pressure because of the mechanical instability.

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Phase diagram of ice polymorphs under negative pressure considering the limits of mechanical stability

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