By coupling bare plasmonic gold nanoparticles (GNPs) with hybrid aluminosilicate nanotubes (Imo-CH3), the photocatalytic activity of the nanotubes is significantly enhanced, with a large part of water reduction occurring directly on the gold surface. The coupling mechanism strongly influences the initial H-2 production rate, which can be greatly increased compared to bare Imo-CH3. This hybrid photocatalytic nano-reactor benefits from a synergy of polarization and confinement effects, facilitating efficient H-2 production.
Hybrid aluminosilicate nanotubes (Imo-CH3) have the ability to trap small organic molecules inside their hydrophobic internal cavity while being dispersed in water owing to their hydrophilic external surface. They also display a curvature-induced polarization of their wall, which favors reduction outside the nanotubes and oxidation inside. Here, we coupled bare plasmonic gold nanoparticles (GNPs) with Imo-CH3 and analyzed for the first time the redox reactivity of these hybrid nano-reactors upon UV illumination. We show that the coupling between GNPs and Imo-CH3 significantly enhances the nanotube photocatalytic activity, with a large part of water reduction occurring directly on the gold surface. The coupling mechanism strongly influences the initial H-2 production rate, which can go from x10 to more than x90 as compared to bare Imo-CH3 depending on the synthesis route of the GNPs. The present results show that this hybrid photocatalytic nano-reactor benefits from a synergy of polarization and confinement effects that facilitate efficient H-2 production.
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