Sub-2 nm Cu and Co Codoping SnO<sub>2</sub> Ultrathin Nanosheet with Mesoporous Structure for Efficient Electrocatalytic Urea Synthesis
Tianbao Zhang, Ping Wang, Cheng Yang, Ying Gao, Jiasai Yao, Senyao Meng, Huawei Li, Rui Tan, Jinlin Liu, Zhenxing Li
Abstract
The production of urea through C–N coupling via the electrochemical coreduction of CO 2 and NO 3 – represents an environmentally friendly and promising approach. However, the C–N coupling reaction encompasses multiple reactants and complex pathways, necessitating a catalyst that exhibits a high efficiency in both CO 2 and NO 3 – reduction. Herein, the sub-2 nm Cu and Co codoped SnO 2 ultrathin nanosheet (SnO 2 CuCo) with mesoporous structure is synthesized for the electrochemical coreduction of CO 2 and NO 3 – for urea synthesis, and the thickness of SnO 2 CuCo is only 1.8 nm, and the mesoporous size in the ultrathin nanosheet is 2 nm. The as-synthesized SnO 2 CuCo achieved a remarkable urea Faraday efficiency (FE) of 50 ± 1% with a production rate as high as 2701.2 ± 99.1 μmol h –1 g cat –1 . Additionally, the SnO 2 CuCo catalyst demonstrated exceptional stability after 10 catalytic cycles. Through in situ spectroscopic analysis combined with density functional theory computations, it has been revealed that Cu doping facilitates the reduction of CO 2 to CO and enhances CO adsorption, favoring the creation of the essential *CO intermediate species. Meanwhile, Co doping effectively reduces the activation energy required for the C–N coupling reaction, thereby promoting the catalytic performance, specifically the activity and selectivity, of the SnO 2 CuCo catalyst in the process of urea synthesis. This finding provides a whole new catalytic strategy for the electrochemical production of urea.