@article{Tan2022, author = {Hao Tan and Qianqian Ji and Chao Wang and Hengli Duan and Yuan Kong and Yao Wang and Sihua Feng and Liyang Lv and Fengchun Hu and Wenhua Zhang and Wangsheng Chu and Zhihu Sun and Wensheng Yan}, title = {Asymmetrical π back-donation of hetero-dicationic Mo4+–Mo6+ pairs for enhanced electrochemical nitrogen reduction}, year = {2022}, journal = {Nano Research}, volume = {15}, number = {4}, pages = {3010-3016}, keywords = {nitrogen reduction reaction, asymmetrical "π back-donation" process, hetero-dicationic Mo4+–Mo6+ pairs, operando experimental characterizations}, url = {https://www.sciopen.com/article/10.1007/s12274-021-3934-6}, doi = {10.1007/s12274-021-3934-6}, abstract = {The breaking of nonpolar N≡N bond of dinitrogen is the biggest dilemma for electrocatalytic nitrogen reduction reaction (NRR) application, driving electron migration between catalysts and N≡N bond (termed “π back-donation” process) is crucial for attenuating interfacial energy barrier but still remains challenging. Herein, using density functional theory calculations, we revealed that constructing a unique hetero-dicationic Mo4+–Mo6+ pair could effectively activate N≡N bond with a lying-down chemisorption configuration by an asymmetrical “π back-donation” process. As a proof-of-concept demonstration, we synthesized MoO2@MoO3 heterostructure with double Mo sites (Mo4+–Mo6+), which are embedded in graphite, for electrochemical nitrogen reduction. Impressively, this hetero-dicationic Mo4+–Mo6+ pair catalysts display more excellent catalytic performance with a high NH3 yield (60.9 µg·h−1·mg−1) and Faradic efficiency (23.8%) as NRR catalysts under ambient conditions than pristine MoO2 and MoO3. Operando characterizations using synchrotron-based spectroscopic techniques identified the emergence of a key *N2Hy intermediate on Mo sites during NRR, which indicates that the Mo sites are active sites and the NRR process tends to follow an associative mechanism. This novel type of hetero-dicationic catalyst has tremendous potential as a new class of transition metal-based catalysts with promising applications in electrocatalysis and catalysts for energy conversion and storage.} }