Special Research Initiatives - Grant ID: SR180100021
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
PFAS source zone remediation by foam fractionation and in situ fluidisation. This project aims to develop two methods for the in situ remediation of per- and poly-fluroalkyl substances (PFAS) contamination, downhole foam fractionation for in situ groundwater treatment, and in situ fluidisation for soil treatment, both separately and in combination. Using these methods, PFASs will be removed in the form of a foam, which will be extracted as a liquid concentrate. These techniques could enable PFAS ....PFAS source zone remediation by foam fractionation and in situ fluidisation. This project aims to develop two methods for the in situ remediation of per- and poly-fluroalkyl substances (PFAS) contamination, downhole foam fractionation for in situ groundwater treatment, and in situ fluidisation for soil treatment, both separately and in combination. Using these methods, PFASs will be removed in the form of a foam, which will be extracted as a liquid concentrate. These techniques could enable PFAS removal efficiencies of greater than 90%, providing entirely new methods for the aggressive removal of PFAS from contaminated source zones. This project will enable the rapid removal of the bulk of the PFAS present in soils and groundwater and reduce the potential for further spreading.Read moreRead less
Polytitanium coagulant for water purification: a systematic investigation to identify mechanisms and benefits over today's technologies. This project will develop a more efficient, environmentally-friendly process for water treatment, using an approach involving titanium that has been attracting interest in recent years, but which is not yet well understood. An Australian-Chinese collaboration will build on existing Australian intellectual property in this project.
Developing an innovative high performance thin-film composite membrane using functionalized nanofibrous support layers for engineered osmosis. Engineered osmosis (EO) is based on the principles of natural osmosis and is an emerging technology for low energy desalination and power generation by pressure-retarded osmosis. However, the process is limited by the challenge of the internal concentration polarisation (ICP) effects experienced when currently available membranes are used. Therefore, the ....Developing an innovative high performance thin-film composite membrane using functionalized nanofibrous support layers for engineered osmosis. Engineered osmosis (EO) is based on the principles of natural osmosis and is an emerging technology for low energy desalination and power generation by pressure-retarded osmosis. However, the process is limited by the challenge of the internal concentration polarisation (ICP) effects experienced when currently available membranes are used. Therefore, the aims of this project are to enhance our understanding of the ICP phenomenon in EO process and to evaluate strategies to mitigate the influence of ICP effects on the performance of the EO process by incorporating innovative functionalised nanofibrous support layers for thin-film composite EO membrane. A significant increase of water flux and mechanical strength is anticipated.Read moreRead less
Composite Mesoporous Solids of TiO2 Nano-Crystals and Silicate as Photo-catalysts for Degradation of Organic Contaminants in Water. TiO2 photo-catalysis is a promising advanced technique for breaking down organic contaminants and bacteria in water and air. This project will develop a novel class of photo-catalysts, the composite meosporous compounds of anatase and layered clay, by combining templated synthesis and pillaring techniques. They will exhibit a high photo-catalytic efficiency with sup ....Composite Mesoporous Solids of TiO2 Nano-Crystals and Silicate as Photo-catalysts for Degradation of Organic Contaminants in Water. TiO2 photo-catalysis is a promising advanced technique for breaking down organic contaminants and bacteria in water and air. This project will develop a novel class of photo-catalysts, the composite meosporous compounds of anatase and layered clay, by combining templated synthesis and pillaring techniques. They will exhibit a high photo-catalytic efficiency with superior properties for practical operations because of the framework of large porosity arising from the arrangement of discrete anatase nano-particles within the silicate layers. The project involves mostly fundamental research into material synthesis, colloid and surface chemistry and photo-catalysis, and aims to develop advanced techniques for water treatment.Read moreRead less
Optimising CDI Water Treatment for Ion Removal and Energy Recovery. This project aims to develop capacitive deionisation (CDI) for the decontamination of water. The specific goals are firstly to identify applications where CDI could cost-effectively make brackish, contaminated water usable. The project then intends to optimise CDI design and operating conditions to remove particular ions of concern and to develop approaches to energy recovery. The main outcome is intended to be a photovoltaic-po ....Optimising CDI Water Treatment for Ion Removal and Energy Recovery. This project aims to develop capacitive deionisation (CDI) for the decontamination of water. The specific goals are firstly to identify applications where CDI could cost-effectively make brackish, contaminated water usable. The project then intends to optimise CDI design and operating conditions to remove particular ions of concern and to develop approaches to energy recovery. The main outcome is intended to be a photovoltaic-powered CDI unit that is capable of stand-alone operation with optimal energy recovery and inbuilt monitoring, and control technology enabling cost-effective and sustainable operation.Read moreRead less
Energy efficient membrane-based hybrid system for sustainable desalination. Seawater desalination plants have been built in Australia in response to increasing pressure on water supplies. The sustainability of these plants is challenged by their significantly high energy cost and concentrated brine output. By exploiting the high residual hydraulic energy contained in the concentrated brine and using it in a membrane-based hybrid system with renewable osmotic energy, this project aims to provide ....Energy efficient membrane-based hybrid system for sustainable desalination. Seawater desalination plants have been built in Australia in response to increasing pressure on water supplies. The sustainability of these plants is challenged by their significantly high energy cost and concentrated brine output. By exploiting the high residual hydraulic energy contained in the concentrated brine and using it in a membrane-based hybrid system with renewable osmotic energy, this project aims to provide solutions for overcoming these challenges. Renewable osmotic energy will be generated from the salinity differences between concentrate and fresh seawater (or other water sources) by pressure retarded osmosis. This will be enabled by the development of highly efficient composite membranes using an electrospinning technique. Read moreRead less
Iron - a solution for uranium resource recovery and pollution response. This project aims to determine key processes controlling uranium transport and fate in natural and engineered environments. This will result in improved efficiency in extracting uranium from tailings and subsurface deposits, reduced risk of contamination of water supplies, and improved management of radioactive waste repositories.
Special Research Initiatives - Grant ID: SR180200015
Funder
Australian Research Council
Funding Amount
$589,007.00
Summary
Combination of electrochemistry with sono to destroy and detoxify PFAS. Previously the major means of dealing with per- and poly-fluoroalkyl substances (PFAS) is by adsorption, to collect and remove PFAS from contaminated sites. However, PFAS still exist, non-degraded and waiting for destruction. Targeting slurry waste from current remediation / adsorption plants, this project aims to efficiently degrade PFAS by combining electrochemical oxidation with sono-chemistry to enhance degradation capac ....Combination of electrochemistry with sono to destroy and detoxify PFAS. Previously the major means of dealing with per- and poly-fluoroalkyl substances (PFAS) is by adsorption, to collect and remove PFAS from contaminated sites. However, PFAS still exist, non-degraded and waiting for destruction. Targeting slurry waste from current remediation / adsorption plants, this project aims to efficiently degrade PFAS by combining electrochemical oxidation with sono-chemistry to enhance degradation capacity, to accelerate PFAS desorption / transportation from slurry waste, to avoid electrode fouling and to detoxify PFAS. The expected outcome of this project is to clean up contaminated sites, including PFAS / precursors and other persistent organic pollutants, leading to significant environmental benefits.Read moreRead less
Special Research Initiatives - Grant ID: SR180100036
Funder
Australian Research Council
Funding Amount
$650,054.00
Summary
Remediation of PFAS in current and legacy biosolids application sites. This project aims to develop novel immobilisation, adsorption and/or thermal destruction methods for biosolids, soil and groundwater in current and legacy per- and poly-fluroalkyl substance (PFAS) sites receiving biosolids. Biosolids generated during waste water treatment carry an unknown potential risk of soil and groundwater PFAS contamination, through their application in agriculture and rehabilitation sites. This project ....Remediation of PFAS in current and legacy biosolids application sites. This project aims to develop novel immobilisation, adsorption and/or thermal destruction methods for biosolids, soil and groundwater in current and legacy per- and poly-fluroalkyl substance (PFAS) sites receiving biosolids. Biosolids generated during waste water treatment carry an unknown potential risk of soil and groundwater PFAS contamination, through their application in agriculture and rehabilitation sites. This project will provide the first major investigation of the release, fate and remediation of perfluorinated compounds in relation to their environmental pathways through wastewater treatment plants in Australia. The data will be evaluated to determine if perfluorinated compounds should be further incorporated into Australian soil and water quality monitoring programs. The project will provide evidence of research advice and methodologies being successfully adopted by water industry end-users, government regulatory agencies and private remediation industries.Read moreRead less