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Amplified Single-Atom U–O Interfacial Effect Originated from U 5<i>f</i>-O 2<i>p</i> Hybridization over UO<sub><i>x</i></sub>/GO for Enhanced Nitrogen Reduction Reaction

Tao Chen, Huanhuan Dong, Tong Liu, Li Zhou, Dengjiang Fu, Beibei Pang, Jie Lian, Tao Ding, Wei Zhang, Rong He, Wenkun Zhu

2023Inorganic Chemistry15 citationsDOIOpen Access PDF

Abstract

Uranium-based catalysts have been regarded as promising candidates for N 2 fixation owing to the low-valent uranium metal active sites possessing the ability to enhance the electron back-donating to the π* antibonding orbitals of N 2 for N≡N dissociation. Herein, we report a directional half-wave rectified alternating current electrochemical method to confine oxygen-rich uranium precursors over ultrathin 2D GO nanosheets. The as-prepared uranium catalysts exhibit a considerable Faradaic efficiency of 12.7% for NH 3 and the NH 3 yield rate of 18.7 μg h –1 mg –1 for N 2 electroreduction. Operando XAS and isotope-labeling FTIR further unravel the preferred nitrogen adsorption reaction intermediate N–(2O ax -1 U-4O eq ) and confirm the key *N 2 H y intermediate species derived from the fed N 2 gas. Theoretical simulations demonstrate that the U–O atomic interface originated from U 5 f -O 2 p orbital hybridization can accumulate partial charge from GO, which can facilitate the N≡N dissociation and lower the thermodynamic energy barrier of the first hydrogenation step.

Topics & Concepts

ChemistryAntibonding molecular orbitalUraniumDissociation (chemistry)CatalysisFaraday efficiencyElectrochemistryMetalNitrogenInorganic chemistryAtomic orbitalPhysical chemistryElectrodeElectronOrganic chemistryQuantum mechanicsMetallurgyPhysicsMaterials scienceAmmonia Synthesis and Nitrogen ReductionCatalytic Processes in Materials ScienceHydrogen Storage and Materials
Amplified Single-Atom U–O Interfacial Effect Originated from U 5<i>f</i>-O 2<i>p</i> Hybridization over UO<sub><i>x</i></sub>/GO for Enhanced Nitrogen Reduction Reaction | Litcius