Preparation, modification, characterization and application of catalysts aiming the degradation of organic pollutant compounds by advanced oxidation processes

This study was focused on the preparation of materials applied to the treatment of organic pollutant compounds. The main idea was to correlate the physical and chemical properties of these materials with their catalytic responses in heterogeneous photocatalysis and ozonation processes. Using the precipitation method, TiO2 and CeO2 mixed oxides were prepared in different proportions. The characterization of these materials showed a correlation between the formation of anisotropic rod-like particles and the capacity of degradation of phenol by a heterogeneous photocatalysis process. It was actived 70% of phenol degradation using the material with 20% CeO2. The interaction between TiO2 and CeO2 was also studied in materials prepared by the sol-gel method. The presence of CeO2 retarded the transition from anatase to rutile polymorphic, as well as maintained the porous structure when the materials were calcinated at 650 ºC. This major stability is related to the photocatalytic properties of the calcinated materials. For instance, 77% of the phenol was degraded using the 0.5% CeO2 photocatalyst. Hybrid photocatalysts composed by SiMgOx and TiO2 were prepared by depositing different amounts of TiO2 on sepiolite plates by slip-casting method. The performances of hybrid materials were evaluated by the degradation of contaminated air with trichloroethylene (TCE) using the heterogeneous photocatalysis process. A correlation between the thickness of the TiO2 layer and the degradation and mineralization rates of TCE was observed, obtaining up to 100% degradation of the TCE. Also, the catalytic properties of the hybrid materials were evaluated by TCE photodegration using solar radiation. A combination of the adsorption properites of the sepiolite and the photocatalytic properties of TiO2 allowed up to 100% of TCE degradation under incidence of solar radiation. The study of hybrid materials was also carried out with the preparation of carbon and CeO2 hybrid spheres. This novel material was prepared in one-pot step, using the hydrothermal method, without organic solvents. The hybrid spheres were used in the degradation of aqueous solution of salicylic acid by the ozonization process. The spheres were possibly formed by a core containing carbon with CeO2 nanoparticles dispersed on their hydrophilic surface.The synergetic effect between the carbon structure and the CeO2 resulted in an increase of 25% in the salicylic acid solution mineralization. (AU)