氢气储存
材料科学
反键分子轨道
密度泛函理论
氢化物
氢
解吸
掺杂剂
合金
焓
电子结构
化学键
化学物理
兴奋剂
物理化学
结晶学
热力学
计算化学
冶金
电子
金属
化学
原子轨道
有机化学
量子力学
光电子学
吸附
物理
作者
Jutao Hu,Xiaoqing Li,Levente Vitos,Stephan Schönecker
出处
期刊:Acta Materialia
[Elsevier BV]
日期:2024-07-15
卷期号:277: 120198-120198
被引量:3
标识
DOI:10.1016/j.actamat.2024.120198
摘要
Refractory high-entropy alloys (HEAs) show promise for novel hydrogen storage technology, but addressing their limited gravimetric hydrogen storage capacity necessitates exploration of light alloying elements including Mg and Al. Here, we employ density-functional theory to investigate the hydrogen desorption energetics of Ti0.325V0.275Zr0.125Nb0.275 alloy and the impact of doping with Mg and Al. Our analysis reveals that Mg and Al addition thermodynamically destabilize the Ti0.325V0.275Zr0.125Nb0.275-hydride and lower its storage capacity. The observed destabilization is attributed to reduced chemical contributions to the desorption enthalpy in the Mg and Al-doped hydrides. Detailed examination of the electronic density of states, electron localization function, and crystal orbital Hamilton population analysis unveils fundamental features of chemical bonding in these hydrides. Notably, H-H antibonding states occur for hydrogen atoms located in the nearest-neighbor interstices of Mg and Al atoms. Charge transfer facilitates formation of these antibonding states. This comprehensive analysis enhances our understanding of the intricate interplay between electronic structure, hydrogen desorption energetics, and chemical bonding in HEA hydrides, offering valuable insights for the design and optimization of advanced hydrogen storage materials.
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