Deteriorated abatement of micropollutants in biological activated carbon filters with aged media: Key role of permeability

Biological activated carbon (BAC) filtration is vital for the abatement of micropollutants in drinking water. However, limited information is available on contaminant removal in BAC filters with aged media (e.g., >6 year) which are commonly operated at water treatment plants, and mechanistic insights into linkages among media age, microbial community, and contaminant removal still lack. In this study, the effects of media age on the abatement of eight micropollutants with various functional groups were investigated. The abatement of micropollutants decreased with increasing media age. Pseudo-first-order rate constants for contaminant removal in 6- and 15-year BAC were (0.3-3.1) × 10^-3 and (0.2-2.6) × 10^-3 s^-1, compared to (0.9-4.3) × 10^-3 s^-1 in 3.5-year BAC filter. Biosorption- and biodegradation-dominated contaminant removal depended on protein and adenosine triphosphate concentrations in biofilm, respectively. Micro-computed tomography revealed the formation of biofilm-dominated clogging with rare voids and channels in 15-year BAC, resulting in low permeability. The decreased permeability led to deficient dissolved O₂ and nutrient supply and thus changed microbial community assembly process, reducing community diversity and function. Core members including families of Saprospiraceae, Chitinophagaceae, Rhodocyclaceae, Comamonadaceae, and Nitrospiraceae in 3.5-year BAC were affiliated with active aerobic metabolism and contaminant biodegradation capacity. Abundances of these functional microbes and genes decreased with increasing media age. Simultaneously, protein in biofilm decreased, thereby decreasing biosorption. The findings of this study reveal the pivotal role of permeability in shaping microbial community and function and the corresponding micropollutant removal in BAC filters with aged media.