Inhibition-level-based carrier selection and kinetic insights for optimised denitrification of saline wastewaters in MBBR

Abstract

The moving bed biofilm reactor (MBBR) provides a high-rate treatment process for the denitrification of saline industrial wastewaters. The carrier structure regulates the biofilm-liquid contact area and can limit the biofilm exposure not only to substrate but also to inhibitors and thus, affects the process performance. However, the potential for biofilms on different carriers to perform differentially under varying salinities remains unexplored as MBBR optimisation strategy. In this study, the nitrogen removal kinetics and biofilm dynamics of methanol-driven denitrification in two MBBRs with a hollow-body and a porous-body carrier were systematically analysed to assess their best performance at salinities 1–9.5 %. Between 1 and 7.5 % salinity, both MBBRs removed over 90 % nitrogen, with the more exposed biofilm in the hollows resulting in higher removal rates. At 9.5 % salinity, the protected biofilm within the pores resulted in a more stable removal (89.5 ± 1.6 %) than in the more exposed hollows (80.9 ± 6.5 %). In both MBBRs, stable and similar denitrifying communities developed, dominated by Paracoccus, Methylovorus and Hyphomicrobium. Moreover, hypersaline (>3.5 %) wastewater from pulp mill NOx-SO2 scrubber was successfully denitrified in MBBRs, showing the potential of biofilm processes for its treatment.