Highly Selective Electroreduction of CO<sub>2</sub> to CH<sub>4</sub> on Cu–Pd Alloy Catalyst: the Role of Palladium‐Adsorbed Hydrogen Species and Blocking Effect
Jinyan Huang, Ye Yang, Xuexue Liang, Bing Chen, Yue Shen, Yan Chen, Jielian Yang, Ying‐lin Yu, Fang Huang, Huibing He, Peican Chen, Liya Zhou, Anxiang Guan
Abstract
Abstract Electroreduction of CO 2 to chemical fuels offers a promising strategy for controlling the global carbon balance and addressing the need for the storage of intermittent renewable energy. In this work, it is demonstrated that tuning adjacent active sites enables the selection of different reaction pathways for generating C 1 or C 2 products during the electroreduction of CO 2 . Cu and Cu–Pd alloy catalysts with different atomic ratios are synthesized and investigated to elucidate their different electroreduction selectivities for CO 2 electroreduction. Cu catalyst favors the formation of C 2 products since the neighboring active Cu sites are beneficial for coupling adjacently adsorbed * CO and * CHO intermediates. Cu alloyed with Pd introduces a blocking effect and increases the intermolecular distance between adjacent adsorbed * CO and * CHO intermediates. Therefore the selectivity for the C 2 H 4 pathway decreas while the CH 4 pathway is enhanced. Moreover, the existence of adsorbed * H species on Pd atoms also played a significant role in boosting CO 2 electroreduction to CH 4 by facilitating the hydrogenation of * CO intermediates. This work reveals the key role of * H species adsorbed on Pd atoms and the blocking effect between active sites for CH 4 formation, which is helpful for the design of copper‐based catalysts for desired products.