Discovery Early Career Researcher Award - Grant ID: DE230101306
Funder
Australian Research Council
Funding Amount
$438,154.00
Summary
Metal organic framework-based membrane for nanoplastics removal . The aim of this project is to understand the fundamental science governing the removal of nanoplastics from wastewater by developing an innovative dually charged metal organic framework based nanocomposite ultrafiltration membrane. The project expects to lead to a breakthrough in our scientific understanding of how nanoplastics and other pollutants can be efficiently removed from wastewater using membranes. The expected outcome is ....Metal organic framework-based membrane for nanoplastics removal . The aim of this project is to understand the fundamental science governing the removal of nanoplastics from wastewater by developing an innovative dually charged metal organic framework based nanocomposite ultrafiltration membrane. The project expects to lead to a breakthrough in our scientific understanding of how nanoplastics and other pollutants can be efficiently removed from wastewater using membranes. The expected outcome is a process that can be used to convert wastewater into freshwater suitable for household, industrial and agricultural use. Such removal could also be of significant environmental benefit, as secondary effluent is a significant source of nanoplastics entering the aquatic environment.Read moreRead less
Fate of PAPs and short-chain PFAS in biosolids amended soils. Biosolids generated during wastewater treatment contain PFAS which are persistent, bioaccumulative and toxic. Application of biosolids to agricultural land may result in soil, groundwater and surface water PFAS contamination via leaching and run-off and pose unknown potential risk to soil health, crops and beneficial biota. This study aims to generate novel knowledge on the PFAS fate in biosolid amended soils, crops and toxicity to ke ....Fate of PAPs and short-chain PFAS in biosolids amended soils. Biosolids generated during wastewater treatment contain PFAS which are persistent, bioaccumulative and toxic. Application of biosolids to agricultural land may result in soil, groundwater and surface water PFAS contamination via leaching and run-off and pose unknown potential risk to soil health, crops and beneficial biota. This study aims to generate novel knowledge on the PFAS fate in biosolid amended soils, crops and toxicity to key soil and aquatic biota at environmentally relevant concentrations. This study is supported by Australian water and its allied industries, as it is important for them to ensure that biosolids application to agricultural land is an environmentally sustainable solution to the Australian farmers and communities.Read moreRead less