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Green ammonia synthesis from the electrochemical nitric oxide reduction reaction (NORR) has evolved as an alternative to the energy-intensive and environmentally polluting Haber-Bosch process. However, it is crucial to develop efficient electrocatalysts to achieve satisfactory green NH3 production via the NORR at low overpotentials with a high selectivity for NH3. Amidst transition metals, copper (Cu) shows ideal N* adsorption free energy to facilitate NH3 production selectively. However, Cu needs a higher over-potential to facilitate multi-protonation steps. In an alkaline medium, protonation hindrance is more severe due to sluggish water dissociation kinetics. Thus, the surface reengineering of Cu with a foreign metal having optimum H* adsorption free energy, such as Ni, could boost the reaction rate at lower overpotentials. In this report, a series of electrocatalysts with different Cu and Ni compositions CuxNi100−x@NC (x = 0-100) supported on N-doped carbon nanostructures are synthesized and their physico-chemical properties and electrochemical NORR performance in 1 M KOH are evaluated. The investigation of NORR performance revealed that CuNi@NC alloys facilitate ammonia production with high faradaic efficiency (FENH) at lower overpotentials than that of pristine Cu100@NC. The optimized alloy, Cu75Ni25@NC, has achieved a remarkable FENH of about 79% with a reasonable ammonia yield rate of 3.6 μmol cm−2 h−1 at an overpotential of 610 mV. The improved NORR to NH3 activity could be attributed to the facile reaction kinetics enabled by the ideal adsorption energies for the NORR intermediates (*N and *H) over the CuNi alloy. Furthermore, we have constructed a Zn-NO battery using a Cu75Ni25@NC cathode for NH3 production. The Zn-NO battery exhibited a high-power density of 3.8 mW cm−2 with 67.33 μg cm−2 h−1 of NH3 yield rate at a discharge potential of 0.6 V vs. Zn. © 2024 The Royal Society of Chemistry.
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