上海科技大学知识管理系统

Environmentally friendly electrochemical reduction of contaminated nitrate to ammonia (NO3−RR) is a promising solution for large quantity ammonia (NH3) production, which, however, is a complex multi-reaction process involving coordination between different reaction intermediates of nitrate reduction and water decomposition-provided active hydrogen (Hads) species. Here, a dual-site catalyst of [W-O] group-doped CoP nanosheets (0.6W-O-CoP@NF) has been designed to synergistically catalyze the NO3−RR and water decomposition, especially the reactions between the intermediates of NO3−RR and water decomposition-provided Hads species. This catalytic NO3−RR exhibits an extremely high NH3 yield of 80.92 mg h−1 cm−2 and a Faradaic efficiency (FE) of 95.2% in 1 m KOH containing 0.1 m NO3−. Significantly, 0.6W-O-CoP@NF presents greatly enhanced NH3 yield and FE in a wide NO3− concentration ranges of 0.001–0.1 m compared to the reported. The excellent NO3−RR performance is attributed to a synergistic catalytic effect between [W-O] and CoP active sites, in which the doped [W-O] group promotes the water decomposition to supply abundant Hads, and meanwhile modulates the electronic structure of Co for strengthened adsorption of Hads and the hydrogen (H2) release prevention, resultantly facilitating the NO3−RR. Finally, a Zn-NO3− battery has been assembled to simultaneously achieve three functions: electricity output, ammonia production, and nitrate treatment in wastewater. © 2023 Wiley-VCH GmbH.