Efficiency of pre-oxidation of natural organic matter for the mitigation of disinfection byproducts: Electron donating capacity and UV absorbance as surrogate parameters.

Pre-oxidation is often used before disinfection with chlorine to decrease the reactivity of the water matrix and mitigate the formation of regulated disinfection byproducts (DBPs). This study provides insights on the impact of oxidative pre-treatment with chlorine dioxide (ClO), ozone (O), ferrate (Fe(VI)) and permanganate (Mn(VII)) on Suwannee River Natural Organic Matter (SRNOM) properties characterized by the UV absorbance at 254 nm (UV) and the electron donating capacity (EDC). Changes in NOM reactivity and abatement of DBP precursors are also assessed. The impact of pre-oxidants (based on molar concentration) on UV abatement ranked in the order O > Mn(VII) > Fe(VI)/ClO, while the efficiency of pre-oxidation on EDC abatement followed the order Mn(VII) > ClO > Fe(VI) > O and two phases were observed. At low specific ClO, Fe(VI) and Mn(VII) doses corresponding to < 50% EDC abatement, a limited relative abatement of UV compared to the EDC was observed (~ 8% EDC abatement per 1% UV abatement). This suggests the oxidation of phenolic-type moieties to quinone-type moieties which absorb UV and don't contribute to EDC. At higher oxidant doses (> 50% EDC abatement), a similar abatement of EDC and UV (~ 0.9-1.2% EDC abatement per 1% UV abatement) suggested aromatic ring cleavage. In comparison to the other oxidants, O abated the relative UV more effectively, due to a more efficient cleavage of aromatic rings. For a pre-oxidation with Mn(VII), ClO and Fe(VI), similar correlations between the EDC abatement and the chlorine demand or the adsorbable organic halide (AOX) formation were obtained. In contrast, O pre-treatment led to a lower chlorine demand and AOX formation for equivalent EDC abatement. For all oxidants trihalomethane formation was poorly correlated with both EDC and UV The EDC abatement was found to be a pre-oxidant-independent surrogate for haloacetonitrile formation. These results emphasize the benefits of combining EDC and UV measurement to understand and monitor oxidant-induced changes of NOM and assessing DBP formation.