Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities fo ....Optical fibre photoreactor for removing airborne molecular contaminants and volatile organic carbons for semiconductor fabrication and fuel cell applications. The collaboration integrates concepts from photocatalysis, optical fibre technology and filtration, to solve important issues in the semiconductor fabrication and fuel cell industries. The project will place Australia amongst the world-leaders in novel integrated photocatalytic/filtration techniques and provide significant opportunities for penetration, in particular, into the US filtration market. The collaboration will afford young Australian-based researchers the opportunity to access technology, expertise and knowledge developed in the US, which is currently unavailable in Australia. It will strengthen ties between UNSW and UMN and provide opportunities for further collaboration.Read moreRead less
Stream power and river morphology in partly-confined valleys of coastal New South Wales, Australia. Rivers in the escarpment-dominated catchments of coastal NSW are characterised by confined and partly-confined valley-settings in which channels have little capacity to adjust. The key aim of this project is to determine controls on the distribution of floodplains in this landscape. Particular attention will be placed on the role played by stream power in determining the relationship between val ....Stream power and river morphology in partly-confined valleys of coastal New South Wales, Australia. Rivers in the escarpment-dominated catchments of coastal NSW are characterised by confined and partly-confined valley-settings in which channels have little capacity to adjust. The key aim of this project is to determine controls on the distribution of floodplains in this landscape. Particular attention will be placed on the role played by stream power in determining the relationship between valley incision and lateral expansion processes along river courses. Understanding controls on these rivers is critical in determining how they modify their form in response to various disturbance events (whether 'natural' of human-induced). Results will provide a rigorous basis with which to explain cross-catchment variability in river forms and processes, aiding our capacity to predict future adjustments to disturbance and develop river management strategies that 'work with nature'.Read moreRead less
Lattice Boltzmann method based simulation of complex microchannels and mixing at micro-scales. The proposed study explores fundamental aspects of microfluidics using new tools, which will enhance the country's database of knowledge. It will lead to the development of a low-cost versatile software package, an important tool for solving microfluidics problems of interest to industries and academics, and will facilitate development and optimization of future microdevices. Further, it will improve A ....Lattice Boltzmann method based simulation of complex microchannels and mixing at micro-scales. The proposed study explores fundamental aspects of microfluidics using new tools, which will enhance the country's database of knowledge. It will lead to the development of a low-cost versatile software package, an important tool for solving microfluidics problems of interest to industries and academics, and will facilitate development and optimization of future microdevices. Further, it will improve Australia's competitiveness in the areas of LBM and MEMS both of which are new techniques with promising applications in their respective areas. The project falls under the National Research Priorities areas of Breakthrough Science and Frontier Technology. The potential applications of the technology encompass several key areas.Read moreRead less
Flotation separation of nanoparticles. This project deals with the separation of fine nanoparticles suspended in water, by attachment to small gas bubbles. It aims to find a way of removing nanoparticles from water, or of separating one species from another. The process could be used for simple solids such as metal oxides, and for biological materials such as large molecules, viruses and small bacteria. The work will be both theoretical and experimental. This ground-breaking project will build u ....Flotation separation of nanoparticles. This project deals with the separation of fine nanoparticles suspended in water, by attachment to small gas bubbles. It aims to find a way of removing nanoparticles from water, or of separating one species from another. The process could be used for simple solids such as metal oxides, and for biological materials such as large molecules, viruses and small bacteria. The work will be both theoretical and experimental. This ground-breaking project will build upon past successes of the applicant, whose invention in the field of resource recovery is contributing close to $1 billion a year to Australia's exports.Read moreRead less
Biomolecular surface interactions with smart biomaterials. Current materials used for medical implants are often recognised by the body as foreign materials causing implant rejection or encapsulation. Research into the interactions between biological molecules and chemically and topographically modified materials will aid in the development of new materials and devices that optimise the body's response to the implanted material. The new materials and surfaces developed from this research will pr ....Biomolecular surface interactions with smart biomaterials. Current materials used for medical implants are often recognised by the body as foreign materials causing implant rejection or encapsulation. Research into the interactions between biological molecules and chemically and topographically modified materials will aid in the development of new materials and devices that optimise the body's response to the implanted material. The new materials and surfaces developed from this research will provide longer lasting implants and reduce the need for repeated operations. This will improve the quality of life for implant recipients and reduce health care costs.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
The Antarctic ice sheet through the Last Glacial Cycle - numerical modelling constrained by field evidence. The response of the world's largest ice mass to climate change is important because melting leads to a rise in sea level. Our ability to predict changes in ice volume and sea level under a warming climate, will be enhanced by better understanding of past ice sheet responses to changes in atmospheric carbon dioxide. Improved numerical models now exist that allow realistic simulations of Ant ....The Antarctic ice sheet through the Last Glacial Cycle - numerical modelling constrained by field evidence. The response of the world's largest ice mass to climate change is important because melting leads to a rise in sea level. Our ability to predict changes in ice volume and sea level under a warming climate, will be enhanced by better understanding of past ice sheet responses to changes in atmospheric carbon dioxide. Improved numerical models now exist that allow realistic simulations of Antarctic ice. These models will be developed further and constrained against existing and new field evidence for the Last Glacial Cycle (last 125,000 years), the period for which we can best define past ice sheet behaviour.Read moreRead less
Microfluidic photonic systems. Australia is set to reap commercial benefits nationally and internationally from new developments in the highly competitive domain of microtechnology. In this project, a group of Australia's leading researchers propose an innovative combination of two exciting fields of scientific research. Microfluidics is the manipulation of minute quantities of liquids in microscopic channels, while photonics is the generation, transmission, detection and analysis of light as a ....Microfluidic photonic systems. Australia is set to reap commercial benefits nationally and internationally from new developments in the highly competitive domain of microtechnology. In this project, a group of Australia's leading researchers propose an innovative combination of two exciting fields of scientific research. Microfluidics is the manipulation of minute quantities of liquids in microscopic channels, while photonics is the generation, transmission, detection and analysis of light as a means to convey, collect and process information. The marriage of these two fields promises the development of novel, high performance tunable devices for sensing, biotechnology and telecommunications.Read moreRead less
Semiconductor Photonic Crystal Devices. Photonic crystals will be a key element of future all-optical ultra-highspeed photonic integrated circuits for telecommunications and signal processing. This project will pioneer new structures capable of manipulating light on integrated photonic chips, based on nano-scale features in semiconductors. This will have a significant impact on Australia's photonics industry.
Restoring hydrological connectivity of surface and ground waters: Biogeochemical processes and environmental benefits for river landscapes. This project examines the restoration of lateral hydrological connectivity to improve floodplain structure and function. The connections between stream flows and both shallow groundwaters and floodplains are critical in sustaining river landscapes. Degrading land and water management practices compounded by natural climatic extremes have severed this link. ....Restoring hydrological connectivity of surface and ground waters: Biogeochemical processes and environmental benefits for river landscapes. This project examines the restoration of lateral hydrological connectivity to improve floodplain structure and function. The connections between stream flows and both shallow groundwaters and floodplains are critical in sustaining river landscapes. Degrading land and water management practices compounded by natural climatic extremes have severed this link. Restoring hydrological connectivity is vital for replenishing groundwater storage and increasing base flows that affect fundamental riverine processes. Using an innovative approach to sustainable agriculture, our project unites multidisciplinary scientific and industry expertise to investigate the biogeochemical and biophysical effects of secondary floodplain channels and in-stream structures on riverine groundwater processes.Read moreRead less