Electro-peroxone process for triclocarban and triclosan removal and reclaimed water disinfection

Abstract

Water reclamation is a known solution to the water scarcity problem; however, concern over water contamination by emerging contaminants and pathogens is growing. This study investigates the simultaneous removal of emerging contaminants and pathogens by applying the continuous-flow electro-peroxone process. Triclocarban (TCC) and triclosan (TCS) were selected as model contaminants of emerging concern, while Escherichia coli strain DH5α was chosen as a representative pathogen. The effects of the initial concentration, water flow rate, and water matrices (direct reclaimed water (treated wastewater), indirect reclaimed water (groundwater), and natural surface water) on TCC, TCS, and E. coli removal were examined. The removal efficiency of TCC (2 mg/L) was up to 92.54 % in 120 min. TCS (non-ozone-resistant compound) was effectively removed in 15 min, while E. coli was instantly inactivated in 3 min. The increase in flow rate decreased the electrical energy per order (EEO) of TCC removal, with the lowest EEO of 19 kWh/m3 at 45 mL/min. The dissolved organic carbon content in water matrices (consuming O3 and H2O2) markedly inhibited the TCC removal, and the kinetic rate as well as reduced 3,4-dichloroaniline (intermediate product) formation. Overall, these findings show the use of the electro-peroxone process is effective in mitigating ozone- and non-ozone-resistant emerging contaminants (TCC and TCS) and pathogens with consideration of water matrices for reclaimed water application.