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Establishing a Theoretical Landscape for Identifying Basal Plane Active 2D Metal Borides (MBenes) toward Nitrogen Electroreduction

Xiangyu Guo, Shiru Lin, Jinxing Gu, Shengli Zhang, Zhongfang Chen, Shiping Huang

2020Advanced Functional Materials194 citationsDOIOpen Access PDF

Abstract

Abstract To achieve efficient ammonia synthesis via electrochemical nitrogen reduction reaction (NRR), a qualified catalyst should have both high specific activity and large active surface area. However, integrating these two merits into one single material remains a big challenge due to the difficulty in balancing multiple reaction intermediates. Here, it is demonstrated that the boron‐analogues of MXenes, namely “MBenes”, could cope with the challenge and achieve the high activity and large reaction region simultaneously toward NRR. Using extensive density functional theory computations and taking 16 MBenes as representatives, it is identified that seven MBenes (CrB, MoB, WB, Mo 2 B, V 3 B 4 , CrMnB 2 , and CrFeB 2 ) not only have intrinsic basal plane activity for NRR with limiting potentials ranging from −0.22 to −0.82 V, but also possess superior capability of suppressing the competitive hydrogen evolution reaction. Particularly, different from the MXenes whose surface oxidation may block the active sites, once oxidized, these MBenes can catalyze NRR via the self‐activating process, reducing O*/OH* into H 2 O* under reaction conditions, and favoring the N 2 electroreduction. As a result, the exceptional activity and selectivity, high active area (≈10 19 m −2 ), and antioxidation nature render these MBenes as pH‐universal catalysts for NH 3 production without introducing any dopants and defects.

Topics & Concepts

MXenesCatalysisRedoxActive siteMaterials scienceElectrochemistryNitrogenDensity functional theoryBasal planeReaction mechanismSelectivityMetalDopantCombinatorial chemistryAmmonia productionLimitingChemistryNanotechnologyComputational chemistryOrganic chemistryPhysical chemistryCrystallographyElectrodeDopingEngineeringMetallurgyMechanical engineeringOptoelectronicsAmmonia Synthesis and Nitrogen ReductionMXene and MAX Phase MaterialsAdvanced Photocatalysis Techniques