Heterogenous Iron Oxide Assemblages for Use in Catalytic Ozonation: Reactivity, Kinetics, and Reaction Mechanism

Heterogeneous catalytic ozonation (HCO) has gained increasing attention as an effective process to remove refractory organic pollutants from industrial effluents. However, widespread application of HCO is still limited due to the typically low efficacy of catalysts used and matrix passivation effects. To this end, we prepared an Al2O3-supported Fe catalyst with high reactivity via a facile urea-based heterogeneous precipitation method. Due to the nonsintering nature of the preparation method, a heterogeneous catalytic layer comprised of gamma-FeOOH and alpha-Fe2O3 is formed on the Al2O3 support (termed NS-FeAl2O3). On treatment of a real industrial effluent by HCO, the presence of NS-Fe-Al2O3 increased the removal of organics by similar to 100% compared to that achieved with a control catalyst (i.e., alpha-Fe2O3/Al2O3 or gamma-FeOOH/Al2O3) that was prepared by a conventional impregnation and calcination method. Furthermore, our results confirmed that the novel NS-Fe-Al2O3 catalyst demonstrated resistance to the inhibitory effect of high concentration of chloride and sulfate ions usually present in industrial effluent. A mathematical kinetic model was developed that adequately describes the mechanism of HCO process in the presence of NS-Fe-Al2O3. Overall, the results presented here provide valuable guidance for the synthesis of effective and robust catalysts that will facilitate the wider industrial application of HCO.

Automated summary

This study presents the preparation and performance of an Al2O3-supported Fe catalyst for heterogeneous catalytic ozonation (HCO). The NS-Fe-Al2O3 catalyst demonstrated significantly improved removal of organic pollutants compared to conventional catalysts. It also exhibited resistance to inhibitory effects of chloride and sulfate ions commonly found in industrial effluents.