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Theoretical inspection of high-efficiency single-atom catalysts based on π-π conjugated holey graphitic g-C7N3 monolayer: Marvelous water-splitting and oxygen reduction reactions activities

Chunyao Fang, Xihang Zhang, Qiang Zhang, Di Liu, Xiaomeng Cui, Jingcheng Xu, Chenglong Shi, Renxian Qin

2024Journal of Material Science and Technology31 citationsDOIOpen Access PDF

Abstract

Hydrogen evolution reaction (HER) and oxygen evolution/reduction reaction (OER/ORR) relying on high-performance and low-cost single-atom catalysts (SACs) driven by renewable energy sources offer a sustainable route to carbon-neutral chemicals and fuels. Herein, first-principles calculations were performed to investigate the catalytic HER/OER/ORR activity of a novel graphitic carbon nitride monolayer (g-C 7 N 3 ) supported single transition metal (TM@g-C 7 N 3 ). High stability as well as positively charged active site (TM-site) and desirable electrical conductivity lay the foundation for TM@g-C 7 N 3 acting as efficient HER/OER/ORR electrocatalysts. We screened out the non-noble-metal Rh@g-C 7 N 3 SAC exhibiting great potential as the trifunctional electrocatalysts for water splitting ( η HER = 0.06 V and η OER = 0.46 V) and a metal-air battery ( η ORR = 0.28 V) on both kinetic and thermodynamic scales, whereas the Ni@g-C 7 N 3 can be served as a bifunctional OER/ORR catalyst with a low overpotential of 0.33 V/0.31 V, for both of which the high thermodynamic stability and oxidation barrier guarantee their outstanding performances at ambient conditions. The mechanism analysis indicates the filling of d-orbital electrons of TM-atom can play an important role in determining the value of an energy descriptor (Δ G OH* ), and the suitable Δ G OH* values make for the TM@g-C 7 N 3 candidates to possess favorable OER/ORR overpotential. Particularly, the Rh-d orbital of Rh@g-C 7 N 3 is evidently hybridized with the OH*-p orbital, resulting in the lone electrons initially distributed in the antibonding orbital pairing up and occupying the downward bonding orbital, ensuring OH* can be adsorbed on Rh@g-C 7 N 3 appropriately. Moreover, multiple-level descriptors including d-band center, COHP, N d , and φ are used to reveal the origin of the electrocatalytic activity.

Topics & Concepts

OverpotentialBifunctionalWater splittingOxygen evolutionChemistryCatalysisElectrocatalystMonolayerMaterials sciencePhysical chemistryNanotechnologyElectrochemistryOrganic chemistryPhotocatalysisElectrodeElectrocatalysts for Energy ConversionAdvanced Memory and Neural ComputingFuel Cells and Related Materials