ABSTRACT Producing ammonia (NH 3 ) by nitrate reduction reaction (NO 3 RR) under acidic conditions has considerable economic value, but there is still a lack of stable and efficient catalysts, due to the complex NO 3 RR process, strongly competing hydrogen evolution reaction (HER), and highly corrosive environment. Herein, a series of Cu‐based catalysts with different Cu atom dispersity on N‐doped carbon are developed for acidic NO 3 RR, where the Cu element can be controlled from single atoms to nanoparticles by tuning the pyrolysis temperature. The catalyst that contains both single atoms and nanoparticles exhibits the optimal electrocatalytic performance, achieving a maximal NH 3 Faraday efficiency of 98.6 % and a high NH 3 yield of 11.8 mg h −1 cm −2 at −0.3 V (vs. RHE) under a strongly acidic environment. Theoretical calculations combined with in‐situ characterization techniques reveal that the coexistence of Cu single atoms and nanoparticles promotes the two‐step relay catalysis, and that the interaction between nanoparticles and surrounding single atoms can optimize the intermediate adsorption, thus reducing the reaction energy barrier of the NO 3 RR process and suppressing competing HER. This work highlights the effects of synergy between single atoms and nanoparticles on boosting tandem catalysis and provides a reasonable reference for developing acidic NO 3 RR electrocatalysts.
Zhang et al. (Tue,) studied this question.