Novel nanostructured high energy cathode material. Recently, the demand for rechargeable batteries has exploded due to the enormous increase in the variety and number of miniaturized devices. It is expected that this demand for high capacity rechargeable batteries as energy sources will become even greater in the future. This program is focused to develop novel high performance cathode materials for lithium rechargeable batteries. The outcomes of the project will be of great benefit to develop ....Novel nanostructured high energy cathode material. Recently, the demand for rechargeable batteries has exploded due to the enormous increase in the variety and number of miniaturized devices. It is expected that this demand for high capacity rechargeable batteries as energy sources will become even greater in the future. This program is focused to develop novel high performance cathode materials for lithium rechargeable batteries. The outcomes of the project will be of great benefit to develop new class rechargeable batteries that are economical, lightweight, environmentlly benign and high energy.Read moreRead less
Hierarchically Structured Graphene-Based Nanoassemblies. Developing high-efficiency, low-cost and environmentally friendly electrochemical energy conversion and storage devices is essential to many consumer electronics. The development of high-performance graphene-based electrode materials in this project will have significant impacts on the Australian economy. This project is expected to help place Australia at the forefront of advanced energy materials and nanotechnology, and enhance the inter ....Hierarchically Structured Graphene-Based Nanoassemblies. Developing high-efficiency, low-cost and environmentally friendly electrochemical energy conversion and storage devices is essential to many consumer electronics. The development of high-performance graphene-based electrode materials in this project will have significant impacts on the Australian economy. This project is expected to help place Australia at the forefront of advanced energy materials and nanotechnology, and enhance the international competitiveness and export power of Australian industry in the high-technology areas. It will also help address the rapidly growing environmental concerns and the increasing global demand for energy.Read moreRead less
Advanced Nanostructured Ceramic Composites for Ultracapacitors. The global climate changes and the related disastrous events such as heat flows, bushfires, and flooding will endanger the Australian population and our natural environment. The implementation of effective devices and technologies to reduce our carbon footprint is a priority task. The project addresses the issue by development of new ultracapacitor materials for next generation green energy storage devices through engineering and im ....Advanced Nanostructured Ceramic Composites for Ultracapacitors. The global climate changes and the related disastrous events such as heat flows, bushfires, and flooding will endanger the Australian population and our natural environment. The implementation of effective devices and technologies to reduce our carbon footprint is a priority task. The project addresses the issue by development of new ultracapacitor materials for next generation green energy storage devices through engineering and implementation of advanced nanoceramics and nanocomposites created by innovative nanotechnologies. The project will also contribute to other national research priorities such as materials and frontier technologies, reduction of atmospheric pollution, and decrease in the energy dependence of our country on oil.Read moreRead less
Improving battery safety with boron nitride nanotube separators. This project aims to improve the safety of lithium ion batteries by developing high –temperature, stable separators. The use of batteries in a hot Australian summer is a major safety issue for our society. This project will develop a new and safe battery technology with the help of boron nitride nanotubes to effectively reduce the risk of thermal runaway of battery cells. The expected outcomes will have a global impact on the safet ....Improving battery safety with boron nitride nanotube separators. This project aims to improve the safety of lithium ion batteries by developing high –temperature, stable separators. The use of batteries in a hot Australian summer is a major safety issue for our society. This project will develop a new and safe battery technology with the help of boron nitride nanotubes to effectively reduce the risk of thermal runaway of battery cells. The expected outcomes will have a global impact on the safety of the current battery technology and the innovative application of boron nitride nanotubes in battery technology. It will position industry on the cutting edge of battery technology required for energy storage development in Australia.Read moreRead less
THEORETICAL AND EXPERIMENTAL STUDIES OF CATALYST DOPING AND DEFECTS IN CARBON NANOTUBES FOR HYDROGEN STORAGE. This project aims to develop a fundamental understanding of the adsorption mechanism of hydrogen in carbon nanotubes through theoretical calculations and experimental studies. This addresses an important area of hydrogen storage in nanomaterials such as carbon nanotubes, which promises efficient and clean energy supply in the hydrogen economy in 15-20 years time. Specifically, the proj ....THEORETICAL AND EXPERIMENTAL STUDIES OF CATALYST DOPING AND DEFECTS IN CARBON NANOTUBES FOR HYDROGEN STORAGE. This project aims to develop a fundamental understanding of the adsorption mechanism of hydrogen in carbon nanotubes through theoretical calculations and experimental studies. This addresses an important area of hydrogen storage in nanomaterials such as carbon nanotubes, which promises efficient and clean energy supply in the hydrogen economy in 15-20 years time. Specifically, the project aims to elucidate the effects of catalyst doping and defects in the carbon nanotube walls on the adsorption mechanism and capacity of hydrogen. Such an understanding is crucial to developing the improved carbon nanotubes with high adsorption capacity.Read moreRead less
The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defect ....The investigation of the effects of catalyst doping, element substitution and defects design in carbon materials for hydrogen storage. The successful introduction of an efficient and clean hydrogen economy is contingent on developing a cost-effective storage technology. Carbon materials have demonstrated significant promise in this area. The project aims to investigate the storage capacity of hydrogen in carbon materials by doping catalysts, substituting elements and introducing designed defects into the structures of carbon materials, with both theoretical and experimental methods. This project also aims to foster a long term linkage with the National Institute of Advanced Industrial Science and Technology, Japan thus enhancing Australian Universities's integration with the research institutions overseas in research and developmentRead moreRead less
New concepts with multidisciplinary approach: novel functionalised nanostructures for hydrogen storage. This project addresses National Research Priorities in the areas of breakthrough science, frontier technologies and advanced materials. Developing new methodologies to fabricate novel functionalised nanostructured materials with tailored properties has great potential in areas including energy storage, novel catalysts, novel sensors, micro/nano-electronics, etc. This project will enhance the i ....New concepts with multidisciplinary approach: novel functionalised nanostructures for hydrogen storage. This project addresses National Research Priorities in the areas of breakthrough science, frontier technologies and advanced materials. Developing new methodologies to fabricate novel functionalised nanostructured materials with tailored properties has great potential in areas including energy storage, novel catalysts, novel sensors, micro/nano-electronics, etc. This project will enhance the international reputation and impact of Australian research in the internationally focused fields of nanotechnology and hydrogen energy technology. Applying innovative nanotechnology to the area of hydrogen energy will add to Australia's export potential and reduce Australia's reliance on foreign fuel sources.
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Spinning Nanosheets for Versatile Applications. This project seeks to develop a highly versatile and innovative fibre spinning research platform for fabricating multifunctional hybrid fibres with unprecedented mechanical, electrical and electrochemical properties. The novel fibres to be produced can be assembled into macroscale architectures or be weaved into functional textiles that can feed into relevant technologies and Australian industries such as advanced textiles for wearable energy stora ....Spinning Nanosheets for Versatile Applications. This project seeks to develop a highly versatile and innovative fibre spinning research platform for fabricating multifunctional hybrid fibres with unprecedented mechanical, electrical and electrochemical properties. The novel fibres to be produced can be assembled into macroscale architectures or be weaved into functional textiles that can feed into relevant technologies and Australian industries such as advanced textiles for wearable energy storage and conversion, microelectrodes and sensors, and smart medical/biomedical platforms. More importantly, this project will have far reaching implications across a range of research disciplines, and ultimately sectors critical to Australia’s health, social, and economic future.Read moreRead less
ARC Centre of Excellence - Australian Centre for Electromaterials Science. The Centre will tackle some of the biggest challenges facing society: those of renewable energy, sustainable industries and enhancing human health. Improvements in all these areas are possible by developing electromaterials with improved efficiency in the generation and transfer of electrical charge. By developing new nano-materials and new theories to explain their behaviour, the Centre will make advances in the areas ....ARC Centre of Excellence - Australian Centre for Electromaterials Science. The Centre will tackle some of the biggest challenges facing society: those of renewable energy, sustainable industries and enhancing human health. Improvements in all these areas are possible by developing electromaterials with improved efficiency in the generation and transfer of electrical charge. By developing new nano-materials and new theories to explain their behaviour, the Centre will make advances in the areas of human health through the regeneration of damaged nerves (eg. in spinal injury) and development of artificial muscles; in renewable energy (plastic solar cells, lightweight batteries and electronic textiles) and in sustainable industries (recovery of precious metals and new corrosion protection technologies).Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882357
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
A Computational Facility for Multi-scale Modelling in Bio and Nanotechnology. Bio- and nanotechnology have the potential to transform Australian industry and research, and to bring significant benefits for consumers. The scope will include materials for energy storage, medical diagnostics and cellular imaging, bioengineering, drug and gene delivery, improved foods by molecular design, novel materials for electronics, improved techniques for particle processing, and molecular sieves for filtering ....A Computational Facility for Multi-scale Modelling in Bio and Nanotechnology. Bio- and nanotechnology have the potential to transform Australian industry and research, and to bring significant benefits for consumers. The scope will include materials for energy storage, medical diagnostics and cellular imaging, bioengineering, drug and gene delivery, improved foods by molecular design, novel materials for electronics, improved techniques for particle processing, and molecular sieves for filtering/purifying water and gases. The dedicated computing facility will enable a fast interactive cycle between simulation and experiment in these areas, accelerating the pace of research and applications.Read moreRead less