Designing plasmon-enhanced photocatalysts for solar-driven water pollutant removal. The outcomes of this program will lead to a new class of composite photocatalysts for efficient water purification using sunlight. Such technology will speed up the transition of Australian environmental and energy industries from a fossil fuel economy to renewable energy economy.
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 nanostructured sensors for ultra-sensitive, label-free and selective detection of biological and chemical species. Outcomes will significantly advance the technical and fundamental understanding of sensor assembly and provide guidelines for developing and manufacturing nanostructured sensors, which is critical for next generation nanoscale sensing platforms for health care, medical diagnostics and chemical detection and Australia's emerging sensor industries.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560683
Funder
Australian Research Council
Funding Amount
$321,953.00
Summary
A furnace stack for advanced photovoltaic, photonic and microfabrication applications. Advanced silicon photovoltaic, photonic, optoelectronic and micro-electromechanical devices require state of the art processing equipment for the deposition of thin dielectric films and for controlled doping of the devices. Key techniques include the deposition of stoichiometric and silicon rich silicon nitride and silicon dioxide films, and the controlled wafer doping with boron and phosphorus. A state of the ....A furnace stack for advanced photovoltaic, photonic and microfabrication applications. Advanced silicon photovoltaic, photonic, optoelectronic and micro-electromechanical devices require state of the art processing equipment for the deposition of thin dielectric films and for controlled doping of the devices. Key techniques include the deposition of stoichiometric and silicon rich silicon nitride and silicon dioxide films, and the controlled wafer doping with boron and phosphorus. A state of the art furnace stack is to be procured which will satisfy these requirements on industrially relevant wafer sizes up to 150mm. The equipment will support a broad range of research projects in the above fields, ranging from fundamental investigations to applied research carried out in collaboration with industry partners.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL180100053
Funder
Australian Research Council
Funding Amount
$3,162,000.00
Summary
Re-discovering liquid metals from core to surface. This project aims to investigate and make new discoveries on the unique properties of liquid metals. Liquid metals have traditionally been used in mining, for switches, barometers, heat transfer units, and coolers and heaters. However, recent discoveries have indicated that liquid metals have untapped potential in applications for creating systems with extraordinary physical and chemical properties. This project will expand our knowledge of liqu ....Re-discovering liquid metals from core to surface. This project aims to investigate and make new discoveries on the unique properties of liquid metals. Liquid metals have traditionally been used in mining, for switches, barometers, heat transfer units, and coolers and heaters. However, recent discoveries have indicated that liquid metals have untapped potential in applications for creating systems with extraordinary physical and chemical properties. This project will expand our knowledge of liquid metals by exploring liquid metals as electron rich solvents and investigating new properties to develop future applications in electronics, optics, catalysts, thermal devices and bio systems.Read moreRead less
Current limiting mechanisms in magnesium diboride superconductors. Numerous important applications have already been identified for MgB2 wire: power transmission cables, fault current limiters, transformers and magnets for motors and generators, as well as MRI. The significant increase in current carrying capacity of one order of magnitude expected to result from the proposed program will enable MgB2 to replace presently existing low-temperature superconductors (LTS) and expensive high-temperat ....Current limiting mechanisms in magnesium diboride superconductors. Numerous important applications have already been identified for MgB2 wire: power transmission cables, fault current limiters, transformers and magnets for motors and generators, as well as MRI. The significant increase in current carrying capacity of one order of magnitude expected to result from the proposed program will enable MgB2 to replace presently existing low-temperature superconductors (LTS) and expensive high-temperature superconductors (HTS) in numerous important applications. MgB2 technology, coupled with renewable energy sources, has the potential to provide a long-term solution to the energy crisis and global warming threat.Read moreRead less
Lithium-Ion Air Batteries with Non-Flammable Ionic Liquid–Based Electrolytes: A Platform to Safety in Lithium-Air Batteries. The aim of this project is to develop rechargeable lithium-ion air batteries based on novel advanced materials and non-flammable ionic-liquid-based electrolytes for use in electric vehicles. The success of this project would make a significant contribution to improving the safety of typical lithium-air batteries. The expected outcomes include: establishing novel lithium-io ....Lithium-Ion Air Batteries with Non-Flammable Ionic Liquid–Based Electrolytes: A Platform to Safety in Lithium-Air Batteries. The aim of this project is to develop rechargeable lithium-ion air batteries based on novel advanced materials and non-flammable ionic-liquid-based electrolytes for use in electric vehicles. The success of this project would make a significant contribution to improving the safety of typical lithium-air batteries. The expected outcomes include: establishing novel lithium-ion air battery electrochemical systems using selected advanced electrode materials and electrolytes which are developed in this proposal; and, understanding the degradation mechanisms of electrode materials in the novel lithium-ion air battery systems with different advanced characterisation methods.Read moreRead less
A novel hybrid electrochemical energy system for both high energy and high power. This project will lead to the development of a new energy-storage system by integrating the advantages of the lithium battery and the supercapacitor. The development of new scientific knowledge during this project will significantly enhance the international competitiveness of Australia in the area of energy storage.
Room Temperature Rechargeable Sulphur Batteries. The project will lead to the development of low cost sulphur rechargeable batteries for electric vehicles and hybrid electric vehicles and will contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. The project will take the incentive in establishing a leading national position in the development of low cost energy storage technology. The Partner Organisation, Nipress, has a close con ....Room Temperature Rechargeable Sulphur Batteries. The project will lead to the development of low cost sulphur rechargeable batteries for electric vehicles and hybrid electric vehicles and will contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. The project will take the incentive in establishing a leading national position in the development of low cost energy storage technology. The Partner Organisation, Nipress, has a close connection to Australia. The company has imported raw materials (metal lead, 8000 tons) from Australia every year. The success of sulphur batteries technology will increase the opportunity of Nipress using more Australian raw materials.
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Development of novel composite anode materials combined with new binders for high energy, high power and long life lithium-ion batteries. This project will lead to better lithium-ion batteries with high energy, high power and long life. Novel composite anode materials combined with new binders will be investigated. The development of new scientific knowledge during this project will significantly enhance the international competitiveness of Australia in the area of clean energy.