Steering artificial photosynthesis via photoinduced conversion of monometallic to bimetallic sites in FeCo nitroprussides
Hao Wang, Gui‐Lin Zhuang, Yingjie Fan, Hua‐Qing Yin, Wei Zhang, Zhe Wu, Shuang Yao, Tong‐Bu Lu, Wenbin Lin, Zhiming Zhang
Abstract
Artificial photosynthesis provides an efficient strategy for solar energy storage via water splitting and CO2 reduction, but it remains a challenge in tuning artificial photosynthesis between these two competing reactions. Herein, we demonstrate photoinduced conversion of monometallic to bimetallic sites in a Fe-Co nitroprusside (FeCo–NP) to steer the reaction path from H2 evolution to CO2 reduction. Monometallic Co sites achieve efficient H2 production with 28.5 mmol g−1 activity and 85.4% selectivity. Photoinduced release of nitrosyl groups from Fe sites generates bimetallic Fe-Co sites, which suppress H2 evolution and enhance CO2 reduction, yielding 31.5 mmol g−1 activity and 87.3% selectivity for C1 products. Mechanistic investigations reveal that monometallic Co sites catalyze H2 evolution via H2O adsorption and O-H cleavage while bimetallic Fe-Co sites facilitate both H2O and CO2 adsorption and subsequent O and C hydrogenation for CO and HCOOH. This work uncovers a strategy to manipulate competing reaction pathways via photoinduced conversion of monometallic to bimetallic sites, which provides unique insights into addressing environmental issues and energy crises. Controlling selectivity between H2O splitting and CO2 reduction remains challenging in artificial photosynthesis. Here, the authors report light-driven conversion of Fe to FeCo bimetallic sites in nitroprusside, switching catalytic selectivity from H2 evolution to CO2 reduction.