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Toward High-Performance Electrochemical Ammonia Synthesis by Circumventing the Surface H-Mediated N <sub>2</sub> Reduction

Zhe Chen, Tao Wang

2024JACS Au15 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide The rapid performance decay with potentials is a significant obstacle to achieving an efficient electrocatalytic N 2 reduction reaction (eNRR), which is typically attributed to competition from hydrogen evolution. However, the potential-dependent competitive behavior and reaction mechanism are still under debate. Herein, we theoretically defined N 2 adsorption, H mediation, and H 2 evolution as three crucial regions along the potentials by revisiting the potential-dependent competitive adsorption between N 2 and H on FeN 4 and RuN 4 catalysts. We revealed that the surface H-mediated mechanism makes eNRR feasible at low potentials but introduces sluggish reaction kinetics, showing a double-edged sword nature. In view of this, we proposed a new possibility to achieve high-performance NH 3 synthesis by circumventing the H-mediated mechanism, where the ideal catalyst should have a wide potential interval with N 2 -dominated adsorption to trigger direct eNRR. Using this mechanistic insight as a new criterion, we proposed a theoretical protocol for eNRR catalyst screening, but almost none of the theoretically reported electrocatalysts passed the assessment. This work not only illustrates the intrinsic mechanism behind the low-performance dilemma of eNRR but also points out a possible direction toward designing promising catalysts with high selectivity and high current density.

Topics & Concepts

ElectrochemistryReduction (mathematics)Ammonia productionAmmoniaChemistryChemical engineeringPhysical chemistryMathematicsElectrodeEngineeringOrganic chemistryGeometryAmmonia Synthesis and Nitrogen ReductionHydrogen Storage and MaterialsMuon and positron interactions and applications
Toward High-Performance Electrochemical Ammonia Synthesis by Circumventing the Surface H-Mediated N <sub>2</sub> Reduction | Litcius