Tan Xingxing, Guo Weiwei, Liu Shoujie, Jia Shunhan, Xu Liang, Feng Jiaqi, Yan Xupeng, Chen Chunjun, Zhu Qinggong, Sun Xiaofu, Han Buxing
Beijing National Laboratory for Molecular Sciences, CAS Key Laboratory of Colloid and Interface and Thermodynamics, CAS Research/ Education Center for Excellence in Molecular Sciences, Institute of Chemistry, Chinese Academy of Sciences Beijing 100190 P. R. China
School of Chemical Sciences, University of Chinese Academy of Sciences Beijing 100049 P. R. China.
Chem Sci. 2022 Sep 26;13(40):11918-11925. doi: 10.1039/d2sc04607e. eCollection 2022 Oct 19.
Current techno-economic evaluation manifests that the electrochemical CO reduction reaction (eCORR) to CO is very promising considering its simple two-electron transfer process, minimum cost of electricity, and low separation cost. Herein, we report a Sn-modification strategy that can tune the local electronic structure of Cu with an appropriate valence. The as-prepared catalysts can alter the broad product distribution of Cu-based eCORR to predominantly generate CO. CO faradaic efficiency (FE) remained above 96% in the wide potential range of -0.5 to -0.9 V the reversible hydrogen electrode (RHE) with CO partial current density up to 265 mA cm. The catalyst also had remarkable stability. Operando experiments and density functional theory calculations demonstrated that the surface Cu sites could be modulated and stabilized after introducing Sn. The Cu sites with low positive valence were conducive to regulating the binding energy of intermediates and resulted in high CO selectivity and maintained the stability of the catalyst. Additionally, scaling up the catalyst into a membrane electrode assemble system (MEA) could achieve a high overall current of 1.3 A with exclusive and stable CO generation.
当前的技术经济评估表明,考虑到电化学CO还原反应(eCORR)生成CO的过程简单,仅涉及两电子转移,且电力成本最低、分离成本低,该反应极具前景。在此,我们报告一种Sn修饰策略,该策略可以调节具有适当化合价的Cu的局部电子结构。所制备的催化剂能够改变基于Cu的eCORR广泛的产物分布,使其主要生成CO。在相对于可逆氢电极(RHE)为-0.5至-0.9 V的宽电位范围内,CO法拉第效率(FE)保持在96%以上,CO分电流密度高达265 mA cm²。该催化剂还具有显著的稳定性。原位实验和密度泛函理论计算表明,引入Sn后,表面Cu位点可以被调节并稳定下来。低价正电荷的Cu位点有利于调节中间体的结合能,从而实现高CO选择性并保持催化剂的稳定性。此外,将该催化剂扩大应用到膜电极组装系统(MEA)中,可以实现1.3 A的高总电流,且能专一且稳定地生成CO。
