In nature titanium dioxide is found in three polymorphic modifications; rutile, anatase and brookite. The most stable form of TiO2 is rutile and crystallizes in a tetragonal crystal system. Semi-conductive material such as TiO2 can be used in heterogeneous photocatalysis. It offer an alternative catalytic oxidation technology because the reactions take place at ambient temperature and pressure. Scientists reported that the TiO2-supported nanoparticles show the best photocatalytic efficiency by simultaneously increasing the rate of phenol development and reduce the formation of hydroquinone by-product. In recent decades, nano-sized TiO2 powders have been used for photocatalysis, in particular for photo-splitting of water and solar energy conversion. However as the size reduces also bandgap energy shifts to higher values reaching energies around 3.2 eV which limits the photocatalytic activity of this material to the UV region i.e. to the wavelengths below 385 nm.
In my work, I optimized photocatalytic activity of the TiO2 catalyst in the conversion of benzene to phenol. At the same time, I was trying to sustain selectivity as high as possible. I first synthesized TiO2, from Ti-complex in concentrations of 1.00 M, 0.50 M, 0.125 M, 0.06 M and 0.03 M. The solutions were hydrothermally treated in teflon lined autoclave for 50 h at 200°C. To determine the shape and the crystal structure of the synthesized material I used scanning electron microscopy (SEM) and X-ray powder diffraction (XRD). In particular with SEM I was able to specify how the specific surface area of TiO2 crystals decreases with decreasing concentration. In the following phase, I used TiO2 powders of different morphology to test the photocatalytic activity for the conversion of benzene to phenol. In the reaction I used distilled water, hydrogen peroxide, acetonitrile and benzene and a UV light as a light source. To increase conversion and selectivity I doped TiO2 with copper. For this I used copper acetate and polyvinylpyrrolidone. Finally, I also tested the effect of gold on conversion and selectivity. I used ethylene glycol and gold chloride. I also found the amount of oxidant optimal for the reaction.
I have concluded that TiO2 alone is not suitable as a catalyst for the photocatalytic reaction of benzene to phenol. However, by doping it with copper the results are much better. Both conversion and selectivity increased with increasing copper content. The best results were obtained with the combination of copper and gold whereas selectivity increased greatly after the addition of gold.
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