New Extraction Membranes and Beads for Use in Industrial Separation. This project involves the development and testing of new polymeric membranes and beads exhibiting high efficiency in the recovery of metal ions from hydrometallurgical solutions. These membranes and beads will also allow effective removal of toxic metal contaminants from wastewater streams before discharge into the environment and clean-up of contaminated natural waters. The research will ultimately lead to: (a) interactions wi ....New Extraction Membranes and Beads for Use in Industrial Separation. This project involves the development and testing of new polymeric membranes and beads exhibiting high efficiency in the recovery of metal ions from hydrometallurgical solutions. These membranes and beads will also allow effective removal of toxic metal contaminants from wastewater streams before discharge into the environment and clean-up of contaminated natural waters. The research will ultimately lead to: (a) interactions with Australian companies involved in metal processing, metal finishing and hydrometallurgy with beneficial effects to Australian industry; (b) training of high quality scientists; and (c) more efficient environmental protection and remediation thus helping to maintain Australia environmentally sustainable.Read moreRead less
Tuning Membrane Chemistry for Desalination and Water Reuse Applications. Climate change has led to a dramatic reduction in the availability of fresh water in southern Australia. Consequently, seawater desalination and wastewater recycling facilities are growing in number and size throughout the country. This project will directly benefit operation of these facilities by providing insight into the fundamentals of the membranes they utilise. The development of better predictive models of performan ....Tuning Membrane Chemistry for Desalination and Water Reuse Applications. Climate change has led to a dramatic reduction in the availability of fresh water in southern Australia. Consequently, seawater desalination and wastewater recycling facilities are growing in number and size throughout the country. This project will directly benefit operation of these facilities by providing insight into the fundamentals of the membranes they utilise. The development of better predictive models of performance will lead to more efficient water production. The project will specifically evaluate the ability of these membranes to retain dangerous contaminants such as endocrine disrupting chemicals and boric acid. Ultimately, the project will lead to lower costs for water production in Australia and better guarantee of supply.Read moreRead less
Development of High Performance Nanocomposite Filtration Membranes: Fabrication and Fouling Mechanisms. This project will develop high performance membranes for the filtration of water and wastewater using novel nanotechnology processes. This will reduce the costs and environmental impact of water treatment and risk from low-level chemical contaminants such as micropollutants. The project will also provide an enhanced technology base for producing low cost, hybrid inorganic-organic materials fo ....Development of High Performance Nanocomposite Filtration Membranes: Fabrication and Fouling Mechanisms. This project will develop high performance membranes for the filtration of water and wastewater using novel nanotechnology processes. This will reduce the costs and environmental impact of water treatment and risk from low-level chemical contaminants such as micropollutants. The project will also provide an enhanced technology base for producing low cost, hybrid inorganic-organic materials for widespread environmental, agricultural and food applications.Read moreRead less
Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the ....Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the next generation of the polymeric products, particularly for application in automotive paint, drug delivery and bio-molecular separations.Read moreRead less
Design of Novel Polymer Micro-Porous Coatings. This project utilises unique polymer structures that self-organise into highly-ordered polymer films. These polymer films have arrays of pores with pore diameters on the micron scale. These films are suitable for high-technology membranes applications, in for instance, biosensors.
The Application of Polymer Inclusion Membranes for the Removal of Thiocyanate and Cyanide from Gold Ore Processing Wastewaters. The recovery of gold at Stawell Gold Mine can be improved by using cyanide and thiocyanate free water in the milling process. The aim of this research is the development of a novel separation technology for the removal of these two ions from mine wastewater to allow it to be recycled. Novel polymeric materials, known as polymer inclusion membranes (PIMs), which have nev ....The Application of Polymer Inclusion Membranes for the Removal of Thiocyanate and Cyanide from Gold Ore Processing Wastewaters. The recovery of gold at Stawell Gold Mine can be improved by using cyanide and thiocyanate free water in the milling process. The aim of this research is the development of a novel separation technology for the removal of these two ions from mine wastewater to allow it to be recycled. Novel polymeric materials, known as polymer inclusion membranes (PIMs), which have never been used before in industrial separation, will be at the centre of this technology. In addition to increasing gold recovery, this technology is expected to reduce substantially the reliance of the Australian goldmining industry on fresh water. This research will also promote PIM based separation as a viable industrial separation technology, applicable in other areas.Read moreRead less
Preparations, Properties, and Applications of New Hydrogels. This project aims to develop a new polymeric matrix system for improved biological separations such as fibrinogen, DNA and RNA. These new hydrogels and membranes will not only be capable of separating biomacromolecules, not possible within the existing systems, but will also develop a new size exclusion type separation system for electrophoresis. The success of the project will have a significant impact in the biotechnology industry. P ....Preparations, Properties, and Applications of New Hydrogels. This project aims to develop a new polymeric matrix system for improved biological separations such as fibrinogen, DNA and RNA. These new hydrogels and membranes will not only be capable of separating biomacromolecules, not possible within the existing systems, but will also develop a new size exclusion type separation system for electrophoresis. The success of the project will have a significant impact in the biotechnology industry. Particularly, it will provide efficient methodologies to fractionate a number of important blood products and strengthen Australian's leading role in this field.Read moreRead less
Photo-enhanced water oxidation using novel structures and conjugated polymers. This project will lead to a more sustainable environment in Australia as it will help reduce greenhouse gas emission from energy consumption. The proposed solar water splitting cell will facilitate an efficient, low-cost and renewable production of hydrogen. Hydrogen is considered to be the ultimate fuel since only water is produced as a product of combustion. Already hydrogen powered fuel cell vehicles are being pro ....Photo-enhanced water oxidation using novel structures and conjugated polymers. This project will lead to a more sustainable environment in Australia as it will help reduce greenhouse gas emission from energy consumption. The proposed solar water splitting cell will facilitate an efficient, low-cost and renewable production of hydrogen. Hydrogen is considered to be the ultimate fuel since only water is produced as a product of combustion. Already hydrogen powered fuel cell vehicles are being produced by a number of the major car manufacturers. The solar water splitting technology based on sustainable materials and the novel cell configuration to be developed in this project will provide the needed stability and efficiency of the cell as well as reduce the manufacturing cost. Read moreRead less