The increasing water scarcity and the urgent need to mitigate climate change demand innovative approaches to wastewater treatment. This abstract explores a promising and novel technological approach that combines Self-Forming Dynamic Membrane Bioreactors (SFDMBRs) with electrochemical processes and algae integration, aiming to reuse wastewater and reduce CO2.
SFDMBRs represent an evolution of conventional Membrane Bioreactors (MBRs), where a dynamic membrane forms in situ on a support structure. The application of an electric field enhances reactor performance by reducing membrane fouling, improving pollutant removal, and potentially disinfecting the effluent. This technology offers several advantages, including high effluent quality, a reduced footprint, and lower operational costs compared to traditional processes. The integration of electrochemical processes, such as electrocoagulation or electrolysis, can further enhance wastewater treatment. These processes effectively remove suspended solids, heavy metals, and other contaminants that are difficult to eliminate through biological treatments alone. Additionally, electrochemical processes facilitate the recovery of valuable resources from wastewater, such as phosphorus or metals.
The incorporation of algae into the system provides an additional treatment layer and an opportunity for CO2 removal. Algae can absorb residual nutrients in wastewater, such as nitrogen and phosphorus, promoting their growth. During photosynthesis, algae consume CO2, contributing to greenhouse gas emission reduction. The resulting algal biomass can be further utilized for bioenergy production or other valuable products.
This combination of technologies offers a sustainable and efficient approach to wastewater treatment. The results demonstrate that the high-quality water obtained enables reuse in various applications, reducing the demand for freshwater resources. Algae-driven CO2 removal helps mitigate climate change. The synergy of SFDMBR, electrochemical processes, and algae has the potential to transform wastewater treatment into a resource-oriented process, contributing to a circular economy. Further research and development are needed to optimize the system and assess its economic feasibility on a large scale.
