Exploiting photocatalysts with environmental friendliness, noble-metal-free and high efficiency is a great challenge for photocatalytic hydrogen evolution under visible light. In this work, we had successfully loaded anatase titanium dioxide… Click to show full abstract
Exploiting photocatalysts with environmental friendliness, noble-metal-free and high efficiency is a great challenge for photocatalytic hydrogen evolution under visible light. In this work, we had successfully loaded anatase titanium dioxide with a special graphene structure [the reduced graphene oxide loaded on amine-functionalized poly (styrene/glycidyl methacrylate) (rGO/PSGM) microspheres. This special structure could greatly improve the catalytic performance of TiO2 in the visible light. The nonmetallic elements (C, N, F, P and S) were doped with TiO2 to further improve the performance of the composite photocatalysts in the visible-light region. After the first-principles density functional theory calculation, the calculated results of the density of states and dielectric function showed that the doped N element has the highest optical absorption capacity. We had proved this through experimental synthesis. Under the full-wavelength illumination, the degradation rate was 20 times higher than that of physically mixed sample; under the visible light, the k value of the degradation rate was 0.0046 min−1 while physically mixed sample had almost no reaction within 5 h. Our study provides a promising approach to achieving efficient photocatalytic reaction under visible light based on TiO2 and graphene without precious metals.
               
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