Nanoporous siloxane membranes for ultrasound mediated ophthalmic drug delivery. This project will develop tailored polymers for use in a novel non-invasive ocular drug delivery device which treats vision threatening conditions such as age-related macular degeneration (AMD). The outcomes of this project will enable an entirely new ocular drug delivery technology, thereby delivering significant benefit to ophthalmic healthcare.
Strength Enhancement of Aluminium Extrusion Alloys via Novel Thermal Processes and Alloy Composition Control. The aluminium industry in Australia produces ~4% of total goods and services exports nationally and over $2 billon per year in export earnings. The importance of developing energy-efficient processing and manufacturing technologies for aluminium and its alloys is reflected in the Federal Government's Light Metals Action Agenda. The proposed project has the potential to establish a platfo ....Strength Enhancement of Aluminium Extrusion Alloys via Novel Thermal Processes and Alloy Composition Control. The aluminium industry in Australia produces ~4% of total goods and services exports nationally and over $2 billon per year in export earnings. The importance of developing energy-efficient processing and manufacturing technologies for aluminium and its alloys is reflected in the Federal Government's Light Metals Action Agenda. The proposed project has the potential to establish a platform for intelligent design and development of thermal processing technologies for aluminium extrusion alloys with improved mechanical properties. Such technologies are expected to help the Australian aluminium industry to expand its international market share.Read moreRead less
Fibre-Polymer Composites With Graded Microstructure. This project concerns the development of a novel fibre-polymer functionally graded composite material that mimics the structure of the spinal disk. The spinal disk comprises a soft core (nucleus) and a tough fibrous periphery (annulus). The graded composite approach of this proposal represents a significant advance over spinal fusion, and over the current generation of spinal disk protheses (metal plates with springs/polymers as shock absorber ....Fibre-Polymer Composites With Graded Microstructure. This project concerns the development of a novel fibre-polymer functionally graded composite material that mimics the structure of the spinal disk. The spinal disk comprises a soft core (nucleus) and a tough fibrous periphery (annulus). The graded composite approach of this proposal represents a significant advance over spinal fusion, and over the current generation of spinal disk protheses (metal plates with springs/polymers as shock absorbers). Chronic back pain affects a significant proportion of the population and is primarily caused by failure of the spinal disk. Therefore a strong social and economic imperative exists to develop engineering solutions to this problem.Read moreRead less
Adhesive Bonding for LoadBearing Joints in Aluminium Fast Ferries. The aim of this project is to investigate new chemical pre-treatment techniques and new sensor technologies for specific use in adhesively bonding aluminium in the Australian Fast Ferry industry. These technologies are important in increasing the use of adhesives in ships, possibly leading to considerable weight savings, which, in turn increases the payload of the vessel. These advances in shipbuilding practice can help maintain ....Adhesive Bonding for LoadBearing Joints in Aluminium Fast Ferries. The aim of this project is to investigate new chemical pre-treatment techniques and new sensor technologies for specific use in adhesively bonding aluminium in the Australian Fast Ferry industry. These technologies are important in increasing the use of adhesives in ships, possibly leading to considerable weight savings, which, in turn increases the payload of the vessel. These advances in shipbuilding practice can help maintain the world-leading status of the Australian Fast Ferry industry. The technology also has the potential to expand the market for Australian-manufactured adhesives. The project also offers a stimulating learning environment for a PhD student.Read moreRead less
Designing starches for increased productivity in mineral flotation. Designing starches for increased productivity in mineral flotation. This project aims to understand the process of starch-mineral surface interactions, and design and develop tailored starch depressant/flocculant biopolymers for mineral beneficiation via the froth flotation process. Natural and modified starches are used as depressants and flocculants in mineral flotation, but scientists lack knowledge of mechanisms describing s ....Designing starches for increased productivity in mineral flotation. Designing starches for increased productivity in mineral flotation. This project aims to understand the process of starch-mineral surface interactions, and design and develop tailored starch depressant/flocculant biopolymers for mineral beneficiation via the froth flotation process. Natural and modified starches are used as depressants and flocculants in mineral flotation, but scientists lack knowledge of mechanisms describing starch-mineral surface interactions, particularly how they process base metal sulphides. This project also intends to develop starch characterisation techniques and novel methods for modifying starch structures and functionalities. Anticipated outcomes are new novel manufacturing applications for starch in Australia.Read moreRead less
Development of the next generation battery storage system for smart grid. Development of the next generation battery storage system for smart grid. This project aims to significantly improve the energy density, safety and robust storage performance of lithium batteries with reduced cost, by developing a next-generation battery with lithium-rich layered oxide cathodes and titanium oxide-based and silicon-based anodes. Intelligent features will make the whole energy network a next-generation batte ....Development of the next generation battery storage system for smart grid. Development of the next generation battery storage system for smart grid. This project aims to significantly improve the energy density, safety and robust storage performance of lithium batteries with reduced cost, by developing a next-generation battery with lithium-rich layered oxide cathodes and titanium oxide-based and silicon-based anodes. Intelligent features will make the whole energy network a next-generation battery storage system, with mechanisms to protect the battery from hazardous and inefficient operating conditions. This lithium ion battery storage system is expected to create opportunities for businesses that harvest renewable energy and make existing industries more environmentally benign.Read moreRead less
A new generation high crash energy absorbing barrier for improved road safety. The new, high energy absorbing road safety barrier developed in this project will provide better protection for all road users than current barriers by reducing the severity of car crashes. Current road barriers result in an average loss of 1600 lives in Australia annually, including a disproportionate number of young lives. The new barrier will be highly efficient in absorbing collisions from vehicles travelling at s ....A new generation high crash energy absorbing barrier for improved road safety. The new, high energy absorbing road safety barrier developed in this project will provide better protection for all road users than current barriers by reducing the severity of car crashes. Current road barriers result in an average loss of 1600 lives in Australia annually, including a disproportionate number of young lives. The new barrier will be highly efficient in absorbing collisions from vehicles travelling at speeds between 60 to over a 100 kilometres per hour. Installation of the new road safety barrier systems in high accident zones will save lives by reducing the severity of accidents involving road barriers. This will significantly benefit the community by reducing injury, medical, rehabilitation and property damage costs, and improve quality of life for all road users.Read moreRead less
Novel plastics using renewable signal chemistry to remove bacteria in water. This project plans to develop synthetic plastic surfaces that continuously generate nitric oxide to deter the formation of biofilms. Plastic surfaces exposed to aqueous environments rapidly become covered by a film of bacteria, which can cause infection. Trace levels of generated nitric oxide can combat this problem by breaking up existing bacterial biofilms. Current research has developed plastics that continuously gen ....Novel plastics using renewable signal chemistry to remove bacteria in water. This project plans to develop synthetic plastic surfaces that continuously generate nitric oxide to deter the formation of biofilms. Plastic surfaces exposed to aqueous environments rapidly become covered by a film of bacteria, which can cause infection. Trace levels of generated nitric oxide can combat this problem by breaking up existing bacterial biofilms. Current research has developed plastics that continuously generate nitric oxide, but not for extended periods of time. This project’s approach is significant because it avoids bacterial resistance to the nitric oxide treatment. Applications of this technology may include removing biofilms from environments such as water filtration devices and consumable medical surfaces.Read moreRead less
Development of advanced lithium ion battery and battery management system for electric /hybrid electric vehicle applications. This project represents a significant scientific and economic development for Australia as it aims to create advanced, high performing, energy storage devices with a focus on safety, that will provide enormous benefits for the environment. An added advantage will be the establishment of local and national expertise in the area of electrochemical energy storage systems, th ....Development of advanced lithium ion battery and battery management system for electric /hybrid electric vehicle applications. This project represents a significant scientific and economic development for Australia as it aims to create advanced, high performing, energy storage devices with a focus on safety, that will provide enormous benefits for the environment. An added advantage will be the establishment of local and national expertise in the area of electrochemical energy storage systems, that will place Australia at the forefront of lithium ion battery research and development. Flow-on benefits will also be created for Australian organizations involved in the manufacturing of electric vehicles and portable devices.Read moreRead less
Synergetic combination of localised internal magnesium diffusion process with cold compaction technique for fabrication of magnesium diboride (MgB2) superconductor wires. This project seeks major advancements in magnesium diboride (MgB2) superconductor performance through the development of novel techniques for the fabrication of MgB2 wire. Further improvement in MgB2 wire performance holds the key to a number of significant commercial applications, including Magnetic Resonance Imaging, fault cu ....Synergetic combination of localised internal magnesium diffusion process with cold compaction technique for fabrication of magnesium diboride (MgB2) superconductor wires. This project seeks major advancements in magnesium diboride (MgB2) superconductor performance through the development of novel techniques for the fabrication of MgB2 wire. Further improvement in MgB2 wire performance holds the key to a number of significant commercial applications, including Magnetic Resonance Imaging, fault current limiters and wind turbines.Read moreRead less