催化作用
尿素
电化学
纳米技术
材料科学
纳米材料
化学
电极
有机化学
物理化学
作者
Jianghui Cao,Fang Zhao,Chengjie Li,Qidong Zhao,Liguo Gao,Tingli Ma,Hao Xu,Xuefeng Ren,Anmin Liu
出处
期刊:Small
[Wiley]
日期:2024-06-27
被引量:1
标识
DOI:10.1002/smll.202403412
摘要
Abstract Industrial urea synthesis production uses NH 3 from the Haber‐Bosch method, followed by the reaction of NH 3 with CO 2 , which is an energy‐consuming technique. More thorough evaluations of the electrocatalytic C−N coupling reaction are needed for the urea synthesis development process, catalyst design, and the underlying reaction mechanisms. However, challenges of adsorption and activation of reactant and suppression of side reactions still hinder its development, making the systematic review necessary. This review meticulously outlines the progress in electrochemical urea synthesis by utilizing different nitrogen (NO 3 − , N 2 , NO 2 − , and N 2 O) and carbon (CO 2 and CO) sources. Additionally, it delves into advanced methods in materials design, such as doping, facet engineering, alloying, and vacancy introduction. Furthermore, the existing classes of urea synthesis catalysts are clearly defined, which include 2D nanomaterials, materials with Mott–Schottky structure, materials with artificially frustrated Lewis pairs, single−atom catalysts (SACs), and heteronuclear dual−atom catalysts (HDACs). A comprehensive analysis of the benefits, drawbacks, and latest developments in modern urea detection techniques is discussed. It is aspired that this review will serve as a valuable reference for subsequent designs of highly efficient electrocatalysts and the development of strategies to enhance the performance of electrochemical urea synthesis.
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