DOI: 10.1002/anie.6942767 ISSN: 1433-7851

In Situ Quantification of Hydrogen Radicals Disentangles Direct and Hydrogen‐Radical‐Mediated Pathways in Green Ammonia Electrosynthesis From Nitrate

Gabriel A. Cerrón‐Calle, Andrea N. Arias‐Sanchez, Marco Flores, Manuel A. Roldan, Carlos M. Sánchez‐Sánchez, Sergi Garcia‐Segura

ABSTRACT

The electrochemical reduction of nitrate (ERN) to ammonia (NH 3 ) has attracted increasing attention as a sustainable route for nitrogen recovery and green ammonia production, enabled by major advances in electrocatalyst design over the past decade. Two mechanistic pathways are generally well‐recognized: direct electron transfer and a hydrogen radical (H*)‐mediated mechanism. However, the latter remains difficult to quantify under practical electrochemical conditions, limiting mechanistic comparison across catalyst configurations. Herein, Ni/Co, Ni/Pt, and Ni/Pt/Co electrocatalysts were investigated to elucidate the interplay between direct and indirect ERN pathways. Quantitative electron spin resonance (ESR) measurements of H* under ERN‐relevant conditions, combined with bulk electrolysis in the absence and presence of an H* scavenger, enabled direct correlation between H* availability and NH 3 production. Ni/Co predominantly follows direct electron transfer, whereas Ni/Pt transitions to an H*‐mediated regime above a threshold current density. In contrast, Ni/Pt/Co exhibits synergistic behavior in which both pathways coexist. Moreover, the H* role varies with electrocatalyst chemical composition, facilitating either NO 3 activation or NO 2 hydrogenation. These findings establish a quantitative framework for resolving H*‐mediated contribution in ERN and provide mechanistic design principles applicable to other electrocatalytic hydrogenation reactions.

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