氢气储存
分子动力学
脱氢
化学
氢
热力学
镁
晶体结构
金属
吉布斯自由能
动能
化学物理
物理化学
计算化学
结晶学
催化作用
有机化学
物理
量子力学
作者
Xiaowang Zhou,ShinYoung Kang,Tae Wook Heo,Brandon C. Wood,Vitalie Stavila,Mark D. Allendorf
出处
期刊:ChemPhysChem
[Wiley]
日期:2019-01-15
卷期号:20 (10): 1404-1411
被引量:5
标识
DOI:10.1002/cphc.201800991
摘要
Magnesium-based materials provide some of the highest capacities for solid-state hydrogen storage. However, efforts to improve their performance rely on a comprehensive understanding of thermodynamic and kinetic limitations at various stages of (de)hydrogenation. Part of the complexity arises from the fact that unlike interstitial metal hydrides that retain the same crystal structures of the underlying metals, MgH2 and other magnesium-based hydrides typically undergo dehydrogenation reactions that are coupled to a structural phase transformation. As a first step towards enabling molecular dynamics studies of thermodynamics, kinetics, and (de)hydrogenation mechanisms of Mg-based solid-state hydrogen storage materials with changing crystal structures, we have developed an analytical bond order potential for Mg-H systems. We demonstrate that our potential accurately reproduces property trends of a variety of elemental and compound configurations with different coordinations, including small clusters and bulk lattices. More importantly, we show that our potential captures the relevant (de)hydrogenation chemical reactions 2H (gas)→H2 (gas) and 2H (gas)+Mg (hcp)→MgH2 (rutile) within molecular dynamics simulations. This verifies that our potential correctly prescribes the lowest Gibbs free energies to the equilibrium H2 and MgH2 phases as compared to other configurations. It also indicates that our molecular dynamics methods can directly reveal atomic processes of (de)hydrogenation of the Mg-H systems.
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