Photocatalytic Synthesis Of P-Anisaldehyde In A Mini Slurry-Bubble Reactor Under Solar Light Irradiation

Dense photocatalyst slurry was employed for the synthesis of p-anisaldehyde under solar light irradiation. An Fe-modified rutile TiO2 (Fe-TiO2, 34.5 m(2)/g) photocatalyst was used as a visible-light-responsive photocatalyst. A conventional TiO2 (P25, 35 m(2)/g) photocatalyst was also examined as a reference catalyst. XRD patterns and diffuse reflectance spectra showed that Fe-TiO2 consists of 100 % rutile phase and absorbs more visible light compared to P25, respectively. The catalyst powder was suspended in an ethyl acetate solution of p-methoxytoluene in the mini-reactor, with oxygen bubbling, under a solar simulator, visible light, and UV LEDs. p-anisaldehyde, as a reaction product, was analyzed by sampling using gas-chromatograph. Regardless of the light source, Fe-TiO2 always outperformed P25 in terms of both generation rates (GR) of p-anisaldehyde and energy requirements (ER). It was demonstrated that the highly dense Fe-TiO2 slurry was efficient for the synthesis under solar light owing to the small size of the reactor. The small amount of Pt and ZrO2 cocatalysts significantly enhanced the GR under solar light. By adopting a visible light responsive Fe-TiO2 photocatalyst, the mini slurry-bubble reactor under solar light achieved a high GR per catalyst mass (CM), which is one to two orders higher than that reported by most previous studies with high-power lamps.