催化作用
纳米材料基催化剂
制氢
材料科学
氢氧化物
氢
化学工程
氨硼烷
吸附
硼氢化
无机化学
硼氢化钠
密度泛函理论
氢气净化器
分解水
氧气
电化学
纳米颗粒
氢燃料
水解
析氧
纳米技术
球磨机
化学
塔菲尔方程
作者
Xin Chen,Zhenyu Wang,Hui Yao,Mingjie Jia,Yiming Wang,Die Shao,Na Ju,Yao Wang,Zilong Liu,Guangwen Xu,Yongjian Ai,Hongbin Sun
出处
期刊:Nano Research
[Springer Science+Business Media]
日期:2026-01-21
卷期号:19 (4): 94908464-94908464
标识
DOI:10.26599/nr.2026.94908464
摘要
Sodium borohydride (NaBH4) solution is a promising liquid "fuel" for continuous hydrogen supply through catalytic hydrolysis, offering a safer alternative to compressed hydrogen to fuel cells. However, the harsh thermal and chemical environments of concentrated NaBH4 hydrolysis cause rapid catalyst deactivation. Herein, we synthesized a high-entropy layered hydroxide nanocatalyst (HELH, FeCoNiCuZn@ZIF-67) via an in-situ etching-growth strategy with ZIF-67. The mechanical structure of residual ZIF-67 inside ensures the robustness of active centers and particles. The efficiency of hydrogen generation is guaranteed by the synergy of different metals in high-entropy structures, which involves borohydride adsorption and H2 release. Benefiting from this cooperative architecture, the HELH catalyst achieves a high hydrogen generation rate of 8 L min-1 g-1 in a 25 wt% NaBH4 solution. Density functional theory and electrochemical analyses reveal that abundant oxygen vacancies and multi-metal synergy optimize water activation and lower the reaction barrier. This work provides an effective strategy for designing robust high-entropy catalysts for extreme conditions.
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