Abstract
The combination of graphene with metal nanoparticles can produce enhanced catalytic properties because of synergistic effects, and has been used to develop highly active catalysts for different applications. However, the mechanism of the synergistic effect between graphene and metal is poorly understood. Here we demonstrate that graphene-coated nickel foam shows a significant catalytic effect on electrodeless metal (gold, platinum, silver, and copper) deposition without any external reducing agent. This is attributed to the formation of an interface dipole layer, induced by the interaction between graphene and nickel. The interface dipole layer catalytic mechanism accelerates metal reduction reaction and explains the simultaneous formation of nickel hydroxide. The nickel hydroxide-wrapped silver hybrid self-assembly developed on the graphene-coated nickel foam serves as an efficient binder-free electrochemical sensor owing to its hierarchical structure.
Highlights
The combination of graphene with metal nanoparticles can produce enhanced catalytic properties because of synergistic effects, and has been used to develop highly active catalysts for different applications
Metal nanoparticle/graphene (MNP/G) composites have been attracting more interest because of remarkably enhanced catalytic property, which is usually ascribed to a synergistic effect from the interface of graphene and active metal nanoparticles[5,10,11,12]
The interface properties of graphene-adsorbed metals have been studied by using first principle theories, which predict the existence of graphene-metal chemical bond and interface diploe layer (IDL)[13,14,15,16]
Summary
The combination of graphene with metal nanoparticles can produce enhanced catalytic properties because of synergistic effects, and has been used to develop highly active catalysts for different applications. The Ag@Ni(OH)2-GNF electrode possesses desirable structural properties including porous Ni(OH)[2] shells for fast molecule diffusion in the electrolyte, highly conductive silver cores for current collection, and large surface area GNF scaffold for combined function of active material loading and current collection. These attributes render Ag@Ni(OH)2-GNF electrode an excellent binder-free sensitive platform for chemical or biological species detection
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