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Molecular study on the growth mechanism of CO2-H2 binary hydrate promoted by electric field.

Authors :
Xu, Jiafang
Yang, Xiaolong
Chen, Jie
Meng, Zhiwei
Wang, Xiaohui
Wang, Bowen
Wang, Jian
Wang, Yahua
Qu, Jingxuan
Qi, Yingxiang
Zhang, Zhilei
Geng, Yuan
Source :
Fuel. May2024, Vol. 363, pN.PAG-N.PAG. 1p.
Publication Year :
2024

Abstract

• The growth rate and the efficiency of capturing H 2 of hydrates can be enhanced by electric fields. • The growth rate of CO 2 -H 2 binary hydrates is inhibited by strong electric fields. • The electric fields accelerate the hydrate formation by altering the orientation of water molecules. • The electric field and CO 2 can collaboratively reduce the growth conditions of H 2 hydrate. The storage and transportation of hydrogen (H 2) are widely recognized as the main challenge of hydrogen utilization technology. The hydrate-based method is one of the safe and environmentally friendly hydrogen storage methods. However, the harsh generation conditions and slow growth rate of H 2 hydrate hinder its industrial application. Therefore, exploring methods to reduce the reaction conditions of H 2 hydrate and improve growth efficiency is worth further research. This study investigated the effect of different intensities of electrostatic fields (0–0.9 V/nm) on the growth of CO 2 -H 2 binary hydrates through molecular dynamics (MD) simulation. Representative parameters such as growth configuration, number of cages, dipole moment, four body angular order parameters, mean square displacement, occupancy rate, etc. were analyzed. The T, P conditions used for the simulation were 255 K, 80 MPa, and 400 ns in duration. The results suggest that a certain range of electric field strength can increase the growth rate of CO 2 -H 2 binary hydrates and reduce the conditions required for hydrogen hydrate formation. The growth-promoting effect of the electric field is primarily manifested in the increased growth rate of binary hydrates. Detailed analysis reveals that electric field of a certain strength can to some extent promote the multiple occupancy of H 2 within cage structures, thereby enhancing the hydrate's ability to capture H 2. These molecular insights are beneficial for the application of electrostatic field in hydrate-based technologies to improving the storage efficiency of H 2 hydrate and the reuse of CO 2. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
00162361
Volume :
363
Database :
Academic Search Index
Journal :
Fuel
Publication Type :
Academic Journal
Accession number :
175698288
Full Text :
https://doi.org/10.1016/j.fuel.2024.130924