A recent review published in Engineering offers an in-depth analysis of the techno-economic and environmental impact of membrane bioreactors (MBRs) used in wastewater treatment. Authored by Tingwei Gao, Yana Jin, and Kang Xiao, the study explores the sustainability of MBRs by examining their economic costs, environmental impacts, and overall techno-economic-environmental performance.

Membrane bioreactors have gained significant attention worldwide due to their superior effluent quality and compact design. However, their high energy consumption and membrane fouling issues pose challenges to their widespread adoption. The review aims to provide a comprehensive understanding of the advantages and disadvantages of MBRs from economic, environmental, and technical perspectives.

The economic analysis of MBRs reveals that their operating costs and energy consumption are generally higher than those of conventional wastewater treatment processes. For instance, the operating costs of MBRs range from 0.09 to 0.45 USD per cubic meter of treated water, compared to 0.02 to 0.40 USD per cubic meter for conventional activated sludge (CAS) processes. Similarly, energy consumption for MBRs is between 0.4 and 1.15 kWh per cubic meter, while CAS processes consume 0.3 to 0.64 kWh per cubic meter. Despite these higher costs, MBRs offer potential benefits such as smaller footprints and higher effluent quality, which can be advantageous in areas with stringent discharge standards.

The environmental impact assessment using life cycle assessment (LCA) shows that MBRs have a positive environmental impact due to their high-quality effluent. However, their global warming potential (GWP) limits their sustainability. The average GWP of MBRs is 1.44 kg CO₂e per cubic meter, compared to 0.84 kg CO₂e per cubic meter for other processes. The high energy consumption associated with aeration and membrane scouring is a significant contributor to the higher GWP of MBRs. Strategies to optimize aeration, increase renewable energy use, and improve energy recovery can help mitigate these environmental impacts.

The review also examines integrated techno-economic-environmental assessment methods such as cost–benefit analysis (CBA), data envelopment analysis (DEA), and multi-criteria decision analysis (MCDA). CBA studies indicate that MBRs are economically viable, with net benefits greater than zero. DEA studies show that while MBRs and conventional processes are comparable in terms of technical efficiency, there is room for improvement in energy efficiency for MBRs. MCDA studies suggest that MBRs have superior technical performance but are less environmentally and economically sustainable compared to conventional processes.

The authors highlight the need for further improvements in the existing assessment methods. They suggest that future research should focus on standardizing LCA implementation, clarifying the scope of assessments, and addressing uncertainties in data and model assumptions. Additionally, the review underscores the importance of considering the full life cycle of MBRs, including construction, operation, and decommissioning, to provide a more comprehensive understanding of their sustainability.

The review provides valuable insights into the techno-economic and environmental performance of MBRs. While MBRs offer significant benefits in terms of effluent quality and compact design, their high energy consumption and environmental impacts need to be addressed to enhance their sustainability. The findings emphasize the need for continued research and development to optimize MBR technology and improve its cost-effectiveness and environmental performance.

The paper “Techno-Economic and Environmental Impact Assessment of Membrane Bioreactors for Wastewater Treatment: A Review,” is authored by Tingwei Gao, Yana Jin, Kang Xiao. Full text of the open access paper: https://doi.org/10.1016/j.eng.2025.05.001. For more information about Engineering, visit the website at https://www.sciencedirect.com/journal/engineering.