Resumen de Novel mechanistic insights on the photoredox degradation of cecs using organic photocatalysts
Water request and water pollution are two bonded problems not only of the last years but also for the future. A lot has been done in the past in order to eliminate contaminants of emerging concerned (CECs) from the aquatic systems, using different kind of techniques; among them, those mediated by light have obtained great attention in the last years, due to their high efficiency and their low costs. Among all these techniques, Advanced Oxidation and Reduction Processes (AOPs and ARPs, respectively) have been developed in order to efficiently remove CECs. In detail, in this thesis the use of organic molecules as photocatalysts has been investigated in combination with solar and visible light; riboflavin and eosin Y have been selected as photocatalysts for their different chemical properties: the first is a natural molecule, well-known for its oxidative properties, while the second one is a synthetic dye.
The main aim of this doctoral thesis was to investigate the degradation of various classes of CECs through the use of organic photocatalysts and visible light. In detail, degradation trends of each CEC was monitored vs time under different working conditions, in order to find the best photodegradation system. Moreover, the operating mechanism was investigated through the determination of the main photoproducts and through the study of the generated reactive species, involved in the processes. Additional toxicity tests were performed in order to have an overall view of all the participants of the system. At the end, all the information was combined to postulate an hypothetical degradation mechanism for all the CECs. More specifically, the thesis could be divided in two main parts: in chapters 3 and 4 oxidation of CECs was carried out, while in chapters 5 and 6 reductive conditions were evaluated.
In detail, in chapters 3 and 4, three pharmaceutical compounds were oxidized in the presence of acetylated riboflavin (RFTA) and visible light. Specifically, carbamazepine, atenolol and noscapine were investigated under oxidative conditions. Photodegradation studies of the initial compounds and of their photoproducts were important in order to understand their natural oxidation in the natural aqueous systems. All the oxidative pathways were considered in a final hypothetical degradation mechanism.
Moreover, in chapters 5 and 6, the photodegradation of a few examples of the benzotriazole UV-stabilizers (BUVSs) was investigated. BUVSs are very recalcitrant compounds, not affected under oxidative conditions. Consequentially, multiple photocatalytic systems were tested and finally, various BUVSs were degraded under reductive conditions in the presence of RFTA or eosin Y (EOY) as photocatalysts, a sacrificial donor as DABCO and visible light. As in the previous chapters, photochemical measurements were necessary to determine the main degradation pathway and the reactive chemical species involved in the process. Additional experiments in the presence of other sacrificial donors and marine water have been performed in order to recreate a real natural environment for future studies.
