Reversed Electron Transfer in Dual Single Atom Catalyst for Boosted Photoreduction of CO 2 .
Yanzhao ZhangBernt JohannessenPeng ZhangJinlong GongJingrun RanShi-Zhang QiaoPublished in: Advanced materials (Deerfield Beach, Fla.) (2023)
Photogenerated charge localization on material surfaces significantly affects photocatalytic performance, especially for multi-electron CO 2 reduction. Dual single atom (DSA) catalysts with flexibly designed reactive sites have received significant research attention for CO 2 photoreduction. However, the charge transfer mechanism in DSA catalysts remains poorly understood. Here we report for the first time a reversed electron transfer mechanism on Au and Co DSA catalysts. In situ characterizations confirm that for CdS nanoparticles (NPs) loaded with Co or Au single atoms, photogenerated eletrons are localized around the single atom of Co or Au. In DSA catalysts however electrons are delocalized from Au and accumulate around Co atoms. Importantly, combined advanced spectroscopic findings and theoretical computation evidence that this reversed electron transfer in Au/Co DSA boosts charge redistribution and activation of CO 2 molecules, leading to highly significantly increased photocatalytic CO 2 reduction, for example, Au/Co DSA loaded CdS exhibits, respectively, ca. 2800% and 700% greater yields for CO and CH 4 compared with that for CdS alone. Reversed electron transfer in DSA can be used for practical design for charge redistribution and to boost photoreduction of CO 2 . Findings will be of benefit to researchers and manufacturers in DSA loaded catalysts for generation of solar fuels. This article is protected by copyright. All rights reserved.