The electrochemical synthesis of ammonia is highly dependent on the coupling reaction between nitrate and water, for which an electrocatalyst with a multifunctional interface is anticipated to promote the deoxygenation and hydrogenation of nitrate with water. Herein, by engineering the surface of bimetallic Ni/Co-MOFs (NiCoBDC) with hydrogen-substituted graphdiyne (HsGDY), a hybrid nanoarray of NiCoBDC@HsGDY with a multifunctional interface has been achieved toward scaleup of the nitrate-to-ammonia conversion. On the one hand, a partial electron transfers from Ni 2+ to the coordinatively unsaturated Co 2+ on the surface of NiCoBDC, which not only promotes the deoxygenation of *NO 3 on Co 2+ but also activates the water-dissociation to *H on Ni 2+ . On the other hand, the conformal coated HsGDY facilitates both electrons and NO 3 − ions gathering on the interface between NiCoBDC and HsGDY, which moves forward the rate-determining step from the deoxygenation of *NO 3 to the hydrogenation of *N with both *H on Ni 2+ and *H 2 O on Co 2+ . As a result, such a NiCoBDC@ HsGDY nanoarray delivers high NH 3 yield rates with Faradaic efficiency above 90% over both wide potential and pH windows. When assembled into a galvanic Zn-NO 3 − battery, a power density of 3.66 mW cm −2 is achieved, suggesting its potential in the area of aqueous Zn-based batteries.
To mimic enzyme in nature, a set of hybrid nanoarrays of Cu-MOFs sealed in hydrogen-substituted graphdiyne has been developed as Lewis acid promoted catalysts. By regulating the electron-withdrawing capability of...
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