材料科学
异质结
催化作用
氧化还原
电流密度
电催化剂
尿素
化学工程
电极
电解
析氧
电化学
电场
无机化学
工作(物理)
氧还原反应
阳极
氧化法
氧气
溶解过程
纳米技术
降级(电信)
过程(计算)
光电子学
作者
Qinhua Xu,常敏 魏,Y Zhou,Jiwei Zhang,Xunwei Ma,Hongjun Wu,Shan He,Zhouhong Ren,Liang Cao,Zhangwen Xie,Ziqi Dang,Li Zhang,Mingxin Ye,Jianfeng Shen
摘要
ABSTRACT The electrocatalytic urea oxidation reaction (UOR) demonstrates significant potential in energy conversion and wastewater treatment. In nickel‐based electrocatalytic systems, the UOR process characterized by NiOOH (Ni 3+ ) formation in the conventional pathway tends to generate harmful by‐products at high potentials while facing oxygen evolution reactuion (OER) competition. Herein, we synthesized a MoS 2 /NiMoO 4 heterostructure and regulate the built‐in electric field in the heterojunction, while the conversion process from Ni 3+ to Ni 2+ is accelerated, thus resulting in a reduction in the static accumulation of Ni 3+ . This delays the cleavage of the carbon‐nitrogen (C─N) bond, thereby steering the reaction pathway toward the complete oxidation products, CO 2 and N 2 . The MoS 2 /NiMoO 4 catalyst exhibits exceptional electrocatalytic activity toward UOR, requiring a low driving potential of just 1.365 V to achieve a current density of 100 mA cm −2 . The urea electrolyzer assembled with MoS 2 /NiMoO 4 and Pt electrodes achieves the same current density at 1.61 V and operates stably for 180 h. This work provides fundamental insights into the UOR mechanism and offers a new direction for designing efficient nickel‐based heterostructure catalysts.
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