Stengl et al [22] have fabricated a

Stengl et al [22] have fabricated a large quantity of graphene nanosheets from natural graphite by using highintensity cavitation field in a high-pressure ultrasonic reactor,then used a well-defined quantity of graphene nanosheets to prepare a nonstoichiometric titania-graphene nanocomposite by thermal hydrolysis of suspension with graphene nanosheets and titania-peroxo complex. Graphene nanosheets with high specific surface area and unique electronic properties were used in this nanocomposite as good supports for TiO2 to enhance the photocatalytic activity. The thermal hydrolysis of the titania-peroxo complex generates spindle-like particles. The direct interaction between TiO2 nanoparticles and graphene sheets prevents the reaggregation of the exfoliated sheets of graphene. Thanks to the presence of H2O2, graphene nanosheets are in part oxidized to graphene oxide nanosheets, and Ti3+ ions are formed. The presence of Ti3+ ions is the origin of the blue coloration which increases with increasing amount of graphene in the solution.
The graphene nanosheets play two roles in the nanocomposite. First, they make Ti3+ ions stable in the TiO2
matrix, and second, they form heterojunctions with titania. Graphene works as sensitizer, and TiO2 works as a substrate in the heterojunction system. Under UV and visible light irradiation, photoinduced electrons on titania surface can easily transfer to graphene nanosheets and, analogosusly, photoinduced holes on the graphene surface would migrate into titania. In this way, the photogenerated electron hole pairs in the catalyst are effectively separated, the probability of the electron–hole recombination is reduced and the photocatalytic activity increased. Moreover, due to the increase of Ti3+ concentration occurring as a result of the valence change
of Ti ion from Ti4+ to Ti3+, surface states act as photocatalytic active sites in the TiO2 surface.