Coagulation of TiO2 nanoparticles-natural organic matter composite contaminants in various aquatic media: Fluorescence characteristics, flocs properties and membrane fouling abilities

摘要

The presence of TiO2 nanoparticles (NPs) influences the efficiency of water and wastewater treatment because of the composite contaminants formed due to the interaction between TiO2 NPs and Natural Organic Matter (NOM). In this study, the coagulation of TiO2 NPs and NOM composite contaminants (TiO2 NPs-NOM) was explored by comparing their fluorescence characteristics, flocs properties, and membrane fouling abilities in different aquatic media (i.e., humic acid synthetic water: WATER(HA), surface water: WATER(XQ); and municipal wastewater: WATER(MW)). Results showed that the TiO2 NPs-NOM removal efficiency depended on the characteristics of NOM in various aquatic media. TiO2 NPs improved the removal efficiency for fluorescent substances from WATER(HA) and WATER(XQ) when the solution pH was 5. However, this removal efficiency declined as the pH was increased to 9. In comparison, the removal efficiency for fluorescent substances from WATER(MW) increased as the TiO2 NPs concentration was increased to 5 mg/L, and then decreased gradually as the TiO2 concentration was increased to 20 mg/L. This is due to the competing adsorption and precipitation reactions between aromatic proteins and NPs. The different TiO2 NPs-NOM in the tested water showed different flocs structures. The fractal dimensions of the flocs in WATER(HA) decreased with increasing TiO2 NPs concentration until it exceeded 10 mg/L, while the fractal dimensions of WATER(MW) flocs increased with increasing TiO2 NPs concentration. This was due to the formation of more loose flocs in the presence of aromatic proteins and soluble microbial byproducts. Total membrane resistance showed little change with increasing TiO2 NPs concentration in the coagulation-ultrafiltration membrane process. The percentages of strongly attached external fouling resistance (Ref-s) and internal fouling resistance (R-if) increased with increasing TiO2 NPs concentration.