纳米孔
联氨(抗抑郁剂)
催化作用
双功能
路易斯酸
材料科学
制氢
氢
无机化学
分解水
化学工程
氢燃料
活化能
锌
纳米技术
离解(化学)
氢键
氢气储存
密度泛函理论
氢经济
化学
反应机理
可持续能源
作者
Yingming Feng,Z H Zhang,Zhonghui Gao,Yanqin Liang,Hui Jiang,ZX Li,Zhenduo Cui,Shengli Zhu,Guilan Fan,Wence Xu
摘要
ABSTRACT The hydrazine oxidation‐assisted hydrogen generation provides a promising alternative for low‐energy hydrogen production. Regulating the atomic structure of the catalyst and optimizing the reaction microenvironment is essential for overcoming the sluggish kinetics of alkaline hydrogen evolution reaction (HER) and hydrazine oxidation reaction (HzOR), yet remains a great challenge. Herein, nanoporous V‐doped Co 2 P (V‐Co 2 P) is introduced as a bifunctional catalyst for HER and HzOR through the regulation of Lewis acidity. The optimized Lewis acidity by V doping facilitates the formation of an ordered hydrogen bond network, accelerating water dissociation and active hydrogen species generation for HER. In addition, the nanoporous V‐Co 2 P can enhance the HzOR catalytic activity by creating a reactant‐enriched local environment, and reduce the energy barrier for converting *N 2 H 3 to *N 2 H 2 . As a result, the nanoporous V‐Co 2 P based electrolyser achieves a current density of 100 mA cm −2 at a low cell potential of 0.13 V. In addition, a self‐powered zinc hydrazine battery and an integrated overall hydrazine splitting system deliver a hydrogen generation rate of 1.12 mmol h −1 cm −2 . The proposed Lewis acidity regulation strategy opens new avenues for designing highly efficient sustainable energy conversion systems.
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