脱氢
材料科学
氢气储存
动能
兴奋剂
球磨机
粒子(生态学)
表面粗糙度
化学工程
氢
粒径
钛合金
冶金
烧结
金属
储能
吸附低温
表面光洁度
合金
作者
Ruilin Zhang,Jianbo Li,Heng Lu,Kunyan Nie,Hongyi Li,Erlin Zhang,Zhen Qiang,Boyu Liu,Yuan Chen,Fusheng Pan
出处
期刊:Rare Metals
[Springer Science+Business Media]
日期:2025-09-08
卷期号:44 (12): 10837-10850
被引量:1
标识
DOI:10.1007/s12598-025-03580-9
摘要
Abstract Rare‐earth magnesium‐based hydrogen storage alloys suffer from the slowly dehydrogenation rates and overly stable thermodynamic properties. Synergistic optimization through alloying and doping is an effective way to improve the hydrogen storage performance. In this study, we explore the preparation of Mg 70 La 25 Ce 5 ‐based alloy using vacuum melting method and the doping of Ti particles by high‐energy mechanical wet ball milling to improve the hydrogen storage performance of the alloy. The results showed that after doping with Ti particles, the roughness of the samples increased, the cracks enlarged, and the surface became more irregular, in which the Mg 70 La 25 Ce 5 + 5 wt% Ti swelled and pulverized after de‐/hydrogenation activation, and the surface shows large cracked web‐like morphology, it can achieve 90% hydrogenation in 20 min at 250 °C and release 3.93 wt% of H 2 in 40 min, and the initial dehydrogenation temperature was reduced; the thermodynamic properties of material effectively improved. Furthermore, the transformation process of MgH 2 and the stable presence of surrounding hydrides during dehydrogenation were investigated through in situ TEM analysis, providing deeper insights into the hydrogen storage mechanism.
科研通智能强力驱动
Strongly Powered by AbleSci AI