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Main-Group p-Block Metal-Doped C<sub>3</sub>N Monolayers as Efficient Electrocatalysts for NO-to-NH<sub>3</sub> Conversion: A Computational Study

Yumeng Yang, Chen Sun, Zhiwen Zhuo, Lei Wang, Weiyi Wang, Aidang Lu, Jiajun Wang

2025Langmuir11 citationsDOI

Abstract

The electrochemical NO reduction reaction (NORR) toward NH 3 synthesis not only helps address issues of air pollution but also holds significant energy and economic value, making it an innovative method with broad application prospects. However, designing NORR electrocatalysts that are both highly active and selective remains a formidable challenge. Herein, we study the main-group p-block metal (M = Al, Ga, and In)-doped C 3 N monolayers as promising single-atom catalysts (SACs) for NORR through spin-polarized first-principles calculations. Our results show that Al@V CC, Al@V CN, Ga@V CC, and Ga@V CN systems are not only stable but also exhibit metallic characteristics, ensuring effective charge transfer during the NORR process. Moreover, nitric oxide (NO) can be strongly chemisorbed and activated on all four candidates with adsorption free energies ranging from −0.83 to −1.59 eV and then spontaneously converted into NH 3 without the need for any applied voltage. More importantly, Ga@V CN possesses a well-suppressed ability for the formation of H 2 /N 2 O/N 2 byproducts, indicating excellent NH 3 selectivity. These findings not only offer a promising electrocatalyst for the NO-to-NH 3 conversion but also highlight the great potential of main-group metals as SACs for electrochemical reactions.

Topics & Concepts

Block (permutation group theory)Group (periodic table)MonolayerMetalDopingMaterials scienceElectrochemistryPhysical chemistryChemistryInorganic chemistryAnalytical Chemistry (journal)ElectrodeCrystallographyNanotechnologyMathematicsOptoelectronicsCombinatoricsOrganic chemistryMetallurgyAmmonia Synthesis and Nitrogen ReductionAdvanced Photocatalysis TechniquesMXene and MAX Phase Materials