无定形固体
材料科学
制氢
壳体(结构)
特征(语言学)
芯(光纤)
纳米技术
生产(经济)
氢
化学工程
结晶学
化学
复合材料
工程类
有机化学
宏观经济学
语言学
哲学
经济
作者
Jiayong Xiao,Chao Jiang,Hui Zhang,Zhuo Xing,Ming Qiu,Yingfeng Yu
标识
DOI:10.1016/s1872-2067(24)60086-0
摘要
Using interface engineering, a highly efficient catalyst with a shell@core structure was successfully synthesized by growing an amorphous material composed of Ni, Mo, and P on Cu nanowires (NiMoP@CuNWs). This catalyst only requires an overpotential of 35 mV to reach a current density of 10 mA cm –2 . The exceptional hydrogen evolution reaction (HER) activity is attributed to the unique amorphous rod-like nature of NiMoP@CuNWs, which possesses a special hydrophilic feature, enhances mass transfer, promotes effective contact between the electrode and electrolyte solution , and exposes more active sites during the catalytic process. Density functional theory revealed that the introduction of Mo weakens the binding strength of the Ni site on the catalyst surface with the H atom and promotes the desorption process of the H 2 product significantly. Owing to its facile synthesis, low cost, and high catalytic performance, this electrocatalyst is a promising option for commercial applications as a water electrolysis catalyst. A highly efficient catalyst with a shell@core structure was synthesized through interface engineering by growing an amorphous material composed of Ni, Mo, and P on Cu nanowires (NiMoP@CuNWs). The hydrophilic catalyst could efficiently generate hydrogen in neutral media, requiring only a 35 mV overpotential to achieve a current density of 10 mA cm –2 .
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