Membrane-aerated biofilm reactor (MABR): recent advances and challenges

Membrane-aerated biofilm reactor (MABR) has been considered as an innovative technology to solve aeration issues in conventional bioreactors. MABR uses a membrane to supply oxygen to biofilm grown on the membrane surface. MABR can perform bubbleless aeration with high oxygen transfer rates, which can reduce energy requirements and expenses. In addition, a unique feature of counter-diffusion creates a stratified biofilm structure, allowing the simultaneous nitrification-denitrification process to take place in a single MABR. Controlling the biofilm is crucial in MABR operation, since its thickness significantly affects MABR performance. Several approaches have been proposed to control biofilm growth, such as increasing shear stress, adding chemical agents (e.g., surfactant), using biological predators to suppress microorganism growth, and introducing ultrasound cavitation to detach biofilm. Several studies also showed the important role of membrane properties and configuration in biofilm development. In addition, MABR demonstrates high removal rates of pollutants in various wastewater treatments, including in full-scale plants. This review presents the basic principles of MABR and the effect of operational conditions on its performance. Biofilm formation, methods to control its thickness, and membrane materials are also discussed. In addition, MABR performance in various applications, full-scale MBRs, and challenges is summarized.

Automated summary

Membrane-aerated biofilm reactor (MABR) is an innovative technology that solves aeration issues in traditional bioreactors. It uses a membrane to provide oxygen to biofilm grown on its surface, allowing bubbleless aeration with high oxygen transfer rates. MABR can also achieve nitrification-denitrification simultaneously due to counter-diffusion. The control of biofilm thickness is crucial for MABR performance and various methods have been proposed, along with the importance of membrane properties and configuration. MABR shows high pollutant removal rates in different wastewater treatments, including full-scale plants.