催化作用
氢气储存
合理设计
催交
氢
材料科学
纳米技术
氢经济
化学
过渡金属
生化工程
化学稳定性
金属
密度泛函理论
作者
Yongxue Zhu,Wenhui Ma,Xingzai Chai,Yunpeng Gu,Yuanxin Wu,Haisheng Chen,Ting Zhang
出处
期刊:Research
[American Association for the Advancement of Science]
日期:2025-01-01
卷期号:8: 1036-1036
被引量:2
标识
DOI:10.34133/research.1036
摘要
MgH 2 (magnesium hydride) has attracted attention as a potential hydrogen storage material owing to its rich availability and high theoretical hydrogen capacity. Nevertheless, its practical utilization is restricted by its high thermodynamic stability and slow hydrogen sorption kinetics. Recent advancements have demonstrated that incorporating various catalytic systems—such as transition metals, metal oxides, metal halides, metal sulfides, and carbon-supported materials—effectively improves hydrogen dissociation, diffusion, and Mg–H bond modulation. Structural transformations, interfacial interactions, and synergistic effects in multicomponent systems substantially enhance MgH 2 performance. Furthermore, cutting-edge computational techniques such as DFT (density functional theory) and ML (machine learning) have become indispensable for expediting catalyst development and forecasting their performance. These computational techniques enable high-throughput screening, provide atomic-scale insights into catalytic mechanisms, and substantially reduce experimental workloads. This review systematically summarizes recent progress in catalytic modifications of MgH 2 , elucidates the underlying enhancement mechanisms, highlights the contributions of DFT and ML methodologies, and discusses future directions such as nanostructuring, multifunctional composite catalysts, and computational-driven rational catalyst design for next-generation hydrogen storage technologies.
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