Size-dependent reactivity of rhodium deuteride cluster anions Rh3Dn− (n = 0–3) toward dinitrogen: The prominent role of σ donation

Nitrogen (N2) fixation is a challenging task for chemists. Adsorption of N2 on transition metal (TM) sites has been identified as a prerequisite for activating the very stable N≡N triple bond in both industrial and biological processes. The importance of π back-donation (filled orbitals of TM → π* o...

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Published in:The Journal of chemical physics 2022-02, Vol.156 (6), p.064303-064303
Main Authors: Cheng, Xin, Li, Zi-Yu, Mou, Li-Hui, Wei, Gong-Ping, Liu, Qing-Yu, He, Sheng-Gui
Format: Article
Language:English
Subjects:
Adsorption
Anions
Biological activity
Chemists
Clusters
Energy levels
Nitrogen
Nitrogenation
Orbitals
Physics
Reactivity
Rhodium
Transition metals
Vapor phases
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container_title The Journal of chemical physics
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creator Cheng, Xin
Li, Zi-Yu
Mou, Li-Hui
Wei, Gong-Ping
Liu, Qing-Yu
He, Sheng-Gui
description Nitrogen (N2) fixation is a challenging task for chemists. Adsorption of N2 on transition metal (TM) sites has been identified as a prerequisite for activating the very stable N≡N triple bond in both industrial and biological processes. The importance of π back-donation (filled orbitals of TM → π* orbitals of N2) between metal sites and N2 has been well elucidated while the role of another classic orbital interaction, namely σ donation (σ orbitals of N2 → empty orbitals of TM), remains ambiguous. Herein, the size-dependent reactivity of trinuclear rhodium deuteride cluster anions Rh3Dn− (n = 0–3) toward N2 adsorption in the gas phase was investigated experimentally and theoretically. A reverse relationship that higher electron-donating ability of clusters corresponds to lower N2 adsorption reactivity was experimentally observed, which is uncommon in N2 activation by gas-phase species. Theoretical analysis revealed that the σ donation rather than the π back-donation plays a predominant role in the adsorption complexes Rh3DnN2− and the enhanced reactivity upon D addition is ascribed to the lowered energy levels of active orbitals in Rh3Dn− as n increases. This study provides the first experimental evidence to declare the important role of σ donation and new clues for the design of reactive metal species in nitrogen fixation.
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Theoretical analysis revealed that the σ donation rather than the π back-donation plays a predominant role in the adsorption complexes Rh3DnN2− and the enhanced reactivity upon D addition is ascribed to the lowered energy levels of active orbitals in Rh3Dn− as n increases. 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source American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list); AIP_美国物理联合会现刊(与NSTL共建)
subjects Adsorption
Anions
Biological activity
Chemists
Clusters
Energy levels
Nitrogen
Nitrogenation
Orbitals
Physics
Reactivity
Rhodium
Transition metals
Vapor phases
title Size-dependent reactivity of rhodium deuteride cluster anions Rh3Dn− (n = 0–3) toward dinitrogen: The prominent role of σ donation
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