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Targeted Modulation of Competitive Active Sites toward Nitrogen Fixation via Sulfur Vacancy Engineering Over MoS<sub>2</sub>

Hao Fei, Ruoqi Liu, Jian Wang, Ting Guo, Zhuangzhi Wu, Dezhi Wang, Fangyang Liu

2023Advanced Functional Materials85 citationsDOI

Abstract

Abstract Electrocatalytic nitrogen reduction reaction (NRR) offers an environmentally benign and sustainable alternative for NH 3 synthesis. However, developing NRR electrocatalysts with both high activity and selectivity remains a significant challenge. Guided by the density functional theory (DFT) calculations and further verified by the experiment, a modulated MoS 2 with well‐controlled S vacancies (MoS 2 ‐Vs) is prepared as an excellent electrocatalyst for NRR, where both the activity and selectivity of NRR mightily rely on the S‐vacancy concentration. The optimized catalyst (MoS 2 ‐7H) in a suitable S‐vacancy concentration (17.5%) is empowered with an excellent NRR activity (NH 3 yield rate: 66.74 µg h − 1 mg − 1 at −0.6 V) and selectivity (Faradic efficiency (FE): 14.68% at −0.5 V). Further mechanistic study reveals that the NRR performance is powerfully concentration‐dependent since its activity is enhanced due to the S‐vacancy‐strengthened N 2 adsorption and reduced reaction energy barrier. Simultaneously, its selectivity is synchronously improved by the steadily enhanced NRR activity and inversely suppressed hydrogen evolution reaction through limiting H 2 desorption kinetics, which sets it markedly apart from other reported defective MoS 2 ‐based catalysts.

Topics & Concepts

SelectivityVacancy defectCatalysisMaterials scienceRedoxDensity functional theoryElectrocatalystNitrogenDesorptionSulfurAdsorptionChemistryPhysical chemistryElectrochemistryComputational chemistryElectrodeCrystallographyOrganic chemistryMetallurgyAmmonia Synthesis and Nitrogen ReductionAdvanced Photocatalysis TechniquesCaching and Content Delivery
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