通过铁-磷原子对促进质子耦合电子转移以增强电化学CO还原反应

Boosting the Proton-coupled Electron Transfer via Fe-P Atomic Pair for Enhanced Electrochemical CO Reduction.

作者信息

Zhang Qiao, Tsai Hsin Jung, Li Fuhua, Wei Zhiming, He Qinye, Ding Jie, Liu Yuhang, Lin Zih-Yi, Yang Xiaoju, Chen Zhaoyang, Hu Fangxin, Yang Xuan, Tang Qing, Yang Hong Bin, Hung Sung-Fu, Zhai Yueming

机构信息

The Institute for Advanced Studies, Wuhan University, Wuhan, 430072, P. R. China.

Department of Applied Chemistry, National Yang Ming Chiao Tung University, 1001 University Road, Hsinchu, 30010, Taiwan.

出版信息

Angew Chem Int Ed Engl. 2023 Oct 26;62(44):e202311550. doi: 10.1002/anie.202311550. Epub 2023 Sep 19.

DOI:10.1002/anie.202311550

PMID:37666796

Abstract

Single-atom catalysts exhibit superior CO -to-CO catalytic activity, but poor kinetics of proton-coupled electron transfer (PCET) steps still limit the overall performance toward the industrial scale. Here, we constructed a Fe-P atom paired catalyst onto nitrogen doped graphitic layer (Fe /PNG) to accelerate PCET step. Fe /PNG delivers an industrial CO current of 1 A with FE over 90 % at 2.5 V in a membrane-electrode assembly, overperforming the CO current of Fe /NG by more than 300 %. We also decrypted the synergistic effects of the P atom in the Fe-P atom pair using operando techniques and density functional theory, revealing that the P atom provides additional adsorption sites for accelerating water dissociation, boosting the hydrogenation of CO , and enhancing the activity of CO reduction. This atom-pair catalytic strategy can modulate multiple reactants and intermediates to break through the inherent limitations of single-atom catalysts.

摘要

单原子催化剂表现出优异的一氧化碳到二氧化碳的催化活性，但质子耦合电子转移（PCET）步骤的缓慢动力学仍然限制了其在工业规模上的整体性能。在此，我们在氮掺杂石墨层（Fe /PNG）上构建了一种铁-磷原子对催化剂，以加速PCET步骤。在膜电极组件中，Fe /PNG在2.5 V时可提供1 A的工业一氧化碳电流，法拉第效率超过90%，比Fe /NG的一氧化碳电流性能高出300%以上。我们还使用原位技术和密度泛函理论解密了铁-磷原子对中磷原子的协同效应，揭示了磷原子为加速水离解、促进一氧化碳氢化以及增强一氧化碳还原活性提供了额外的吸附位点。这种原子对催化策略可以调节多种反应物和中间体，突破单原子催化剂的固有局限性。

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通过铁-磷原子对促进质子耦合电子转移以增强电化学CO还原反应

Boosting the Proton-coupled Electron Transfer via Fe-P Atomic Pair for Enhanced Electrochemical CO Reduction.

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