Abstract

Electrocatalytic nitrate reduction to ammonia holds great promise for developing green technologies for electrochemical ammonia energy conversion and storage. Considering that real nitrate resources often exhibit low concentrations, it is challenging to achieve high activity in low-concentration nitrate solutions due to the competing reaction of the hydrogen evolution reaction, let alone considering the catalyst lifetime. Herein, we present a high nitrate reduction performance electrocatalyst based on a Co nanosheet structure with a gradient dispersion of Ru, which yields a high NH₃ Faraday efficiency of over 93% at an industrially relevant NH₃ current density of 1.0 A/cm² in 2000 ppm NO₃^- electrolyte, while maintaining good stability for 720 h under −300 mA/cm². The electrocatalyst maintains high activity even in 62 ppm NO₃^- electrolyte. Electrochemical studies, density functional theory, electrochemical in situ Raman, and Fourier-transformed infrared spectroscopy confirm that the gradient concentration design of the catalyst reduces the reaction energy barrier to improve its activity and suppresses the catalyst evolution caused by the expansion of the Co lattice to enhance its stability. The gradient-driven design in this work provides a direction for improving the performance of electrocatalytic nitrate reduction to ammonia.

Achieving stable and high-activity nitrate electroreduction to ammonia in low concentrations nitrate is critical but challenging. Here, the authors present a Co-based electrocatalyst with gradient-doped Ru atoms, showing a continuous ammonia production at −1000 mA/cm² in 2000 ppm nitrate electrolyte.