First principles molecular dynamics study of filled ice hydrogen hydrate
We investigated structural changes, phase diagram, and vibrational properties of hydrogen hydrate in filled-ice phase C2 by using first principles molecular dynamics simulation. It was found that the experimentally reported “cubic” structure is unstable at low temperature and/or high pressure: The “...
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sg-ntu-dr.10356-1017692023-02-28T19:42:37Z First principles molecular dynamics study of filled ice hydrogen hydrate Zhang, Jingyun Kuo, Jer-Lai Iitaka, Toshiaki School of Physical and Mathematical Sciences DRNTU::Science::Chemistry::Analytical chemistry::Gas analysis We investigated structural changes, phase diagram, and vibrational properties of hydrogen hydrate in filled-ice phase C2 by using first principles molecular dynamics simulation. It was found that the experimentally reported “cubic” structure is unstable at low temperature and/or high pressure: The “cubic” structure reflects the symmetry at high (room) temperature where the hydrogen bond network is disordered and the hydrogen molecules are orientationally disordered due to thermal rotation. In this sense, the “cubic” symmetry would definitely be lowered at low temperature where the hydrogen bond network and the hydrogen molecules are expected to be ordered. At room temperature and below 30 GPa, it is the thermal effects that play an essential role in stabilizing the structure in “cubic” symmetry. Above 60 GPa, the hydrogen bonds in the framework would be symmetrized and the hydrogen bondorder-disorder transition would disappear. These results also suggest the phase behavior of other filled-ice hydrates. In the case of rare gas hydrate, there would be no guest molecules’ rotation-nonrotation transition since the guest molecules keep their spherical symmetry at any temperature. On the contrary methane hydrate MH-III would show complex transitions due to the lower symmetry of the guest molecule. These results would encourage further experimental studies, especially nuclear magnetic resonance spectroscopy and neutron scattering, on the phases of filled-ice hydrates at high pressures and/or low temperatures. Published version 2014-02-17T07:05:49Z 2019-12-06T20:44:19Z 2014-02-17T07:05:49Z 2019-12-06T20:44:19Z 2012 2012 Journal Article Zhang, J., Kuo, J.- L., & Iitaka, T. (2012). First principles molecular dynamics study of filled ice hydrogen hydrate. The Journal of Chemical Physics, 137(8), 084505. 0021-9606 https://hdl.handle.net/10356/101769 http://hdl.handle.net/10220/18805 10.1063/1.4746776 en The journal of chemical physics © 2012 American Institute of Physics. This paper was published in The Journal of Chemical Physics and is made available as an electronic reprint (preprint) with permission of American Institute of Physics. The paper can be found at the following official DOI: [http://dx.doi.org/10.1063/1.4746776]. One print or electronic copy may be made for personal use only. Systematic or multiple reproduction, distribution to multiple locations via electronic or other means, duplication of any material in this paper for a fee or for commercial purposes, or modification of the content of the paper is prohibited and is subject to penalties under law. application/pdf |
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DRNTU::Science::Chemistry::Analytical chemistry::Gas analysis Zhang, Jingyun Kuo, Jer-Lai Iitaka, Toshiaki First principles molecular dynamics study of filled ice hydrogen hydrate |
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We investigated structural changes, phase diagram, and vibrational properties of hydrogen hydrate in filled-ice phase C2 by using first principles molecular dynamics simulation. It was found that the experimentally reported “cubic” structure is unstable at low temperature and/or high pressure: The “cubic” structure reflects the symmetry at high (room) temperature where the hydrogen bond network is disordered and the hydrogen molecules are orientationally disordered due to thermal rotation. In this sense, the “cubic” symmetry would definitely be lowered at low temperature where the hydrogen bond network and the hydrogen molecules are expected to be ordered. At room temperature and below 30 GPa, it is the thermal effects that play an essential role in stabilizing the structure in “cubic” symmetry. Above 60 GPa, the hydrogen bonds in the framework would be symmetrized and the hydrogen bondorder-disorder transition would disappear. These results also suggest the phase behavior of other filled-ice hydrates. In the case of rare gas hydrate, there would be no guest molecules’ rotation-nonrotation transition since the guest molecules keep their spherical symmetry at any temperature. On the contrary methane hydrate MH-III would show complex transitions due to the lower symmetry of the guest molecule. These results would encourage further experimental studies, especially nuclear magnetic resonance spectroscopy and neutron scattering, on the phases of filled-ice hydrates at high pressures and/or low temperatures. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Zhang, Jingyun Kuo, Jer-Lai Iitaka, Toshiaki |
| format |
Article |
| author |
Zhang, Jingyun Kuo, Jer-Lai Iitaka, Toshiaki |
| author_sort |
Zhang, Jingyun |
| title |
First principles molecular dynamics study of filled ice hydrogen hydrate |
| title_short |
First principles molecular dynamics study of filled ice hydrogen hydrate |
| title_full |
First principles molecular dynamics study of filled ice hydrogen hydrate |
| title_fullStr |
First principles molecular dynamics study of filled ice hydrogen hydrate |
| title_full_unstemmed |
First principles molecular dynamics study of filled ice hydrogen hydrate |
| title_sort |
first principles molecular dynamics study of filled ice hydrogen hydrate |
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2014 |
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https://hdl.handle.net/10356/101769 http://hdl.handle.net/10220/18805 |
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1759857551795552256 |