Density functional theory studies of hydrogen bonding vibrations in sI gas hydrates
Author(s) -
Haocheng Wang,
Xu-Liang Zhu,
Jing-Wen Cao,
Xiao-Ling Qin,
Ye-Chen Yang,
Tian-Xiao Niu,
YingBo Lu,
Peng Zhang
Publication year - 2020
Publication title -
new journal of physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.584
H-Index - 190
ISSN - 1367-2630
DOI - 10.1088/1367-2630/abb54c
Subject(s) - density functional theory , methane , intermolecular force , hydrogen bond , physics , molecular vibration , molecule , supercell , phonon , atom (system on chip) , clathrate hydrate , bond length , atomic physics , molecular physics , hydrate , condensed matter physics , chemistry , organic chemistry , quantum mechanics , thunderstorm , meteorology , computer science , embedded system
To analyze the vibrational modes of water and methane in structure I gas hydrates, we constructed a 178-atom supercell with two small cages of type 5 12 and six large cages of type 5 12 6 2 . We applied the density functional theory method to simulate the vibrational spectrum and normal modes of methane hydrates. In accord with our previous studies, we confirmed that two groups of hydrogen bond (H-bond) peaks (at around 291 and 210 cm −1 ) in the translational bands come from two kinds of intermolecular H-bond vibrational modes. This is the first investigation of H-bond vibrations in methane hydrates. The partial modes of CH 4 were extracted. We found that the CH 4 phonons in the translational region are below 180 cm −1 so that the influence of methane on the H-bond is insignificant. We proposed a new method to decompose gas hydrates via direct application of terahertz radiation to the H-bonds. Herein, we confirmed that CH 4 molecules do not absorb this energy.
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