Cu-Induced Interfacial Water Engineering of SnO<sub>2</sub> for Durable and Highly Selective CO<sub>2</sub> Electroreduction
Benqiang Tian, Haoyang Wu, Yaning Zhang, Chengjin Chen, Kovan Khasraw Abdalla, Marshet Getaye Sendeku, Linlin Zhou, Jiage Yu, Yuan Wang, Yun Kuang, Haijun Xu, Jiazhan Li, Xiaoming Sun
Abstract
The behavior of interfacial water is a crucial factor in influencing the selectivity of CO 2 reduction. However, modulating the behavior of interfacial water is challenging, and the investigation of its mechanism is still insufficient. In this regard, we present a Cu doping strategy to engineer the interfacial water of the SnO 2 electrode. Amorphous SnO 2 catalysts with uniformly doped Cu are prepared by using a coprecipitation method. Our results indicate that the introduction of Cu lowers the oxidation state of Sn and stabilizes surface Sn–O species by enhanced covalency of Sn–O bonds, which suppresses competitive water adsorption and promotes activation of CO 2 . Additionally, in situ spectroscopy reveals a blue shift of the H 2 O peak and easier *OCHO formation, indicating that the incorporation of Cu promotes the dissociation of interfacial water and *CO 2 hydrogenation process. The optimized Cu–SnO 2 catalyst exhibits a high formate Faradaic efficiency (>90%) in a wide current range (100–1000 mA cm –2 ). This study provides insights into the behavior of interfacial water and sheds light on the design of efficient CO 2 electroreduction catalysts.