Litcius/Paper detail

Removal of nitrogen from wastewater: Unsolved problems and possible solutions with partial denitrification/anammox systems

Joanna Majtacz, Hussein E. Al‐Hazmi, Xianbao Xu, Grzegorz Piechota, Xiang Li, Gopalakrishnan Kumar, Tejraj M. Aminabhavi, Mohammad Reza Saeb, Michaël Badawi, Jacek Mąkinia

2024Chemical Engineering Journal25 citationsDOIOpen Access PDF

Abstract

• PD/A is an innovative process for N removal from side/main streams wastewater. • PD offers an effective method for supplying NO 2 − to anammox process. • Challenges and strategies for initiating and restoring PD/A are explored. • Optimal TNRE in PD/A depends on adjusting substrate levels and operational parameters. • Solutions are proposed to stabilize the PD/A systems. Nitrate (NO 3 − ) is more stable than ammonia (NH 4 + ) and nitrite (NO 2 − ) among the majority of emerging pollutants in wastewater that can harm the ecosystem by depleting oxygen and water quality, thereby posing environmental and human health risks. Despite anaerobic ammonium oxidation (anammox) being a common method for nitrogen (N) removal from wastewater, it leaves behind residual NO 3 − of around 11 %. Maintaining the stability of N removal in the mainstream of wastewater (50–60 mg/L) is challenging due to the lack of intrinsic factors that suppress nitrite-oxidizing bacteria (NOB) and the accumulation of NO 3 − . Recently, partial denitrification/anammox (PD/A) has been recognized as a useful approach to eliminate NO 3 − and NH 4 + from the sidestream (≥500 mg/L of N) and mainstream wastewater simultaneously. This review explores the complexities of sustaining stability in PD/A systems, including managing fluctuating NH 4 + and NO 3 – levels while keeping a COD/N ratio of ≤ 3 to facilitate optimal NO 2 − production for the anammox. This review discusses the significance of temperature, pH, free ammonia, and free nitrous acid levels for optimal total N removal efficiency and PD/A stability in the long term. Strategies used for initiating and restoring the PD/A systems include optimized inoculum selection, granular sludge seeding, stepwise acclimation, bioaugmentation, unique substance incorporation, and innovative system design. Additionally, various strategies aim to enhance the stability by modifying the substance composition, introducing inorganic carbon and NO 3 − , incorporating heavy metals, embedding the biomass in gel carriers, adding microalgae, and adjusting hydraulic and solids retention time. These solutions aim to address the challenges to improve stability in the PD/A process. Future research roadmaps and supporting portfolios should address advancements and emerging technologies tackling the ongoing challenges in PD/A systems. These developments emphasize the significance of wastewater treatment for sustainable water availability to support the United Nations Sustainable Development Goal 6 (UN SDG 6) established in 2015.

Topics & Concepts

AnammoxDenitrificationWastewaterNitrogenEnvironmental scienceSewage treatmentEnvironmental engineeringEnvironmental chemistryWaste managementChemistryEngineeringDenitrifying bacteriaOrganic chemistryWastewater Treatment and Nitrogen RemovalMicrobial Fuel Cells and BioremediationModular Robots and Swarm Intelligence