Visible luminescence improvement of ZnO/PAA nano-hybrids by silica coating

The effect of a silica coating on the improvement of the visible light emission properties of ZnO/polyacrylic acid (PAA) nanohybrids is reported. The synthesized material consists of ZnO nanocrystals incorporated into the PAA mesospheres and then coated with silica. The silica amount can be controlled by the concentration of ammonia used in the sol-gel process as catalyst. The interaction between PAA and ammonia is crucial, the presence of the former tending to inhibit the catalytic action of the latter. We show that there is an optimum of the silica amount around the mesospheres, which leads to a drastic increase in the defect-related visible photoluminescence quantum yield of ZnO nanocrystals. A six-fold increase of the quantum yield can thus be achieved, reaching competitive values higher than 60%. This optimum is a compromise between a complete protective silica layer around the mesospheres and too thick a layer inducing inefficient absorption of excitation light by the coating.

Automated summary

A silica coating on ZnO/PAA nanohybrids can significantly enhance the visible light emission properties, with an optimal amount of silica leading to a six-fold increase in the quantum yield of ZnO nanocrystals. The interaction between PAA and ammonia during the sol-gel process plays a crucial role in controlling the silica amount and ultimately improving the photoluminescence quantum yield.