Addressing the ever-demanding crisis of water scarcity, Dr Mohit Aggarwal, Assistant Professor from the Department of Civil Engineering, has published a paper titled “Polyculture Microalgae and Zno/GAC-nanocomposite System for Greywater Treatment” in the Q1 journal Biomass and Bioenergy with an impact factor of 5.8. In his research, Dr Aggarwal explores sustainable methods to treat wastewater with algae and nanoparticles, providing an efficient method to reuse greywater and reduce water consumption.
Abstract
This study explores sustainable greywater treatment using microalgae and a ZnO/GAC nanocomposite in a 15-day batch photobioreactor. The system achieved significant nutrient removal, with 80% TOC, 94.2% PO43−, and 99.6% NH4+ efficiencies. Microalgal growth was enhanced by the nanocomposite, reaching a density of 1.8 g/L. The resulting biomass had a high heating value of 18.32 MJ/kg. The ZnO/GAC nanocomposite maintained effective removal over four cycles. The treated greywater met reuse standards for toilet flushing, with pH 8.5, turbidity <4 NTU, and COD, NH4+, and PO43− of 34, 0.032, and 0.48 mg/L, respectively.
Explanation of the research in layperson’s terms
Water scarcity and pollution are serious problems, and our research aims to find an environmentally friendly way to treat greywater (wastewater from sinks, showers, etc.). We explored the use of algae combined with special nanoparticles (zinc oxide) to clean the water more effectively. The algae grow in the water and help remove harmful substances like carbon, phosphorus, and nitrogen. The nanoparticles make this process even more efficient.
After treatment, the water is clean enough to be reused, for example, in toilet flushing. This method not only helps clean wastewater but also provides a sustainable way to reuse it, which can reduce water consumption and help the environment.
Practical implementation/ Social implications of the research
Practical implementation
The system developed in this research can be implemented in decentralised greywater treatment units, especially in water-scarce areas. It provides a cost-effective, eco-friendly solution for treating household or industrial greywater. The treated water meets the quality standards for reuse in applications like toilet flushing or landscape irrigation, reducing freshwater demand.
Social implications
This research promotes water recycling, contributing to sustainable water management practices and helping to address water scarcity issues. This can improve access to water in communities with limited resources, reduce the pressure on freshwater supplies, and lower the environmental impact of wastewater discharge, leading to healthier ecosystems and communities. Additionally, adopting such systems on a larger scale can foster greater awareness of water conservation and responsible resource usage.
