Heterogeneous catalytic ozonation: The significant contribution of PZC value and wettability of the catalysts

The aim of this study is to evaluate the role of PZC and wettability of the catalysts in heterogeneous catalytic ozonation process. For that purpose, 18 solid materials examined as potential catalysts for heterogeneous catalytic ozonation, regarding the degradation of small amounts (4 mu\M) of p-chlorobenzoic acid (p-CBA - typical micropollutant) at pH 7. The examined catalysts belong to three main categories, i.e., metal oxides/hydroxides, minerals, and carbons. Alumina 507, SiO2, Bayoxide, zeolite, calcite and dolomite were found to be the optimum catalysts with p-CBA removal rates higher than 99.4% after the 3rd min of the process. The obtained results indicate the importance of surface charge and the wettability degree of the catalysts. It was found that the affinity between ozone and the catalyst surface and the subsequent production of hydroxyl radicals ((OH)-O-center dot) depends on these parameters. More specifically catalysts of high wettability and neutrally to slightly positive surface charged led to enhanced p-CBA degradation. The strongly negative or positive surface charged materials that present low wettability were found to decrease the (OH)-O-center dot production. Although, in the gas phase ozone presents better affinity with the non-polar/hydrophobic surfaces, when it is dissolved in water and participates in aqueous phase oxidation reactions, the contact with the catalysts' surface is enhanced by the higher wettability of the solids, promoting the production of (OH)-O-center dot. In addition to the activation of ozone on the catalysts' surface, it was shown that their efficiency is enhanced by the initial p-CBA adsorption on the surface of applied catalysts.

Automated summary

This study evaluated the role of PZC and wettability of catalysts in the heterogeneous catalytic ozonation process. Results showed that catalysts with high wettability and neutral to slightly positive surface charge led to enhanced degradation of pollutants, while materials with strongly negative or positive surface charge and low wettability decreased the production of hydroxyl radicals. Ozone's affinity with catalyst surfaces and production of hydroxyl radicals were found to depend on surface charge and wettability, highlighting the importance of these parameters in the process.