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Surface Oxophilicity Driven <sup>*</sup> N Pathway Tuning for Selective Nitrate Electroreduction to Nitrogen

Yuting Cong, Hui Wang, Lin Gu, Ziyang Wu, Min Kuang, Jianping Yang

2026Advanced Materials15 citationsDOIOpen Access PDF

Abstract

ABSTRACT Electrochemical reduction of nitrate to nitrogen (N 2 ) offers a sustainable pathway to close the nitrogen cycle and mitigate nitrate pollution. However, for Cu, Co, and other transition‐metal catalysts, high N 2 selectivity has mainly relied on breakpoint chlorination, which consumes large amounts of chlorine and poses secondary contamination risks. Here, we introduce a surface‐oxophilicity strategy to steer the * N pathway, thereby enhancing both catalytic efficiency and intrinsic nitrogen selectivity. Among oxophilicity‐modified Pd, Sn doping emerged as the optimal configuration. The resulting PdSn metallene aerogels achieve remarkable NO 3 − ‐N conversion (∼97%) and N 2 selectivity (∼99%), together with long‐term stability (&gt;600 h) and broad tolerance to variable nitrate concentrations. In situ characterization and theoretical analyses reveal that Sn‐induced oxophilicity strengthens nitrogen‐oxygen intermediate adsorption, ensuring sufficient * N availability for N‐N coupling while elevating the hydrogenation barrier of * N → * NH, thus suppressing NH 3 formation. Integrated into a Zn‐NO 3 − battery and a customized gas‐integrated flow electrolyzer, the catalyst enables efficient nitrate removal and nearly complete N 2 selectivity, offering a promising platform for sustainable nitrogen recycling and energy conversion.

Topics & Concepts

NitrateMaterials scienceCatalysisNitrogenSelectivityElectrochemistryBattery (electricity)Inorganic chemistryNOxCoupling (piping)Chemical engineeringChlorineReactive nitrogenSustainable energyEnergy storageElectrochemical energy conversionFaraday efficiencyNanotechnologyPlatinumEnergy transformationSelective catalytic reductionElectrodeDopingReduction (mathematics)Reactive nitrogen speciesAmmonia Synthesis and Nitrogen ReductionEnvironmental remediation with nanomaterialsMetalloenzymes and iron-sulfur proteins