Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560959
Funder
Australian Research Council
Funding Amount
$165,000.00
Summary
The Macquarie National Low Temperature Optoelectronic Thin Film Growth Facility. Funding is requested for an Australian facility for the growth of nitride and oxide thin films with in-situ optical analysis equipment for the monitoring of growth parameters. It is envisaged that this facility would be for the development of materials and device structures for photonic, electronic and optoelectronic applications. The facility will also provide a leading Australian source of these materials for fund ....The Macquarie National Low Temperature Optoelectronic Thin Film Growth Facility. Funding is requested for an Australian facility for the growth of nitride and oxide thin films with in-situ optical analysis equipment for the monitoring of growth parameters. It is envisaged that this facility would be for the development of materials and device structures for photonic, electronic and optoelectronic applications. The facility will also provide a leading Australian source of these materials for fundamental material studies utilising nuclear analysis and implantation technologies, high resolution X-ray diffraction, high spatial resolution micro-cathodoluminescence and other forms of analysis. Ex-situ optical analysis equipment is also requested for post-growth evaluation to compliment and evaluate the in-situ analysis.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101759
Funder
Australian Research Council
Funding Amount
$385,720.00
Summary
A novel fundamental approach to enable net shape manufacturing of low-cost high-performance titanium alloys . Oxygen is the bottleneck issue of titanium powder metallurgy, which radically deteriorates the ductility of titanium. This project aims to develop the essential fundamental knowledge and technical solutions to mitigate the detrimental effect of oxygen on the ductility of as-sintered titanium products and enable the net-shape fabrication of low-cost high-performance titanium alloys. This ....A novel fundamental approach to enable net shape manufacturing of low-cost high-performance titanium alloys . Oxygen is the bottleneck issue of titanium powder metallurgy, which radically deteriorates the ductility of titanium. This project aims to develop the essential fundamental knowledge and technical solutions to mitigate the detrimental effect of oxygen on the ductility of as-sintered titanium products and enable the net-shape fabrication of low-cost high-performance titanium alloys. This will be achieved by utilising the inexpensive and unique titanium hydride powder, rather than titanium metal powder, and by developing effective oxygen scavengers. The outcomes will form a robust basis for the creation of a viable titanium hydride powder metallurgy business.Read moreRead less
Net shape manufacturing of titanium alloys by powder metallurgy. This project is aiming at developing a novel net shape manufacturing for advanced materials (titanium alloys) and addresses Priority Goal of Advanced Materials of Research Priority 3: Frontier Technologies for Advanced Materials. It represents new science and innovative engineering and has the potential to produce valuable new intellectual property.
Discovery Early Career Researcher Award - Grant ID: DE180101030
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Monoatomic metal doping of carbon-based nanomaterials for hydrogen storage. This project aims to present a new concept of monoatomic metal doped carbon-based nanomaterials as advanced solid-state hydrogen storage materials (S-HSMs) for hydrogen fuel cells. The key feature for this synthesis is the use of the unique “defect” structures in carbon lattice as the efficient anchoring sites to immobilise the metal species at atomic level. This project is expected to create new knowledge of atomic inte ....Monoatomic metal doping of carbon-based nanomaterials for hydrogen storage. This project aims to present a new concept of monoatomic metal doped carbon-based nanomaterials as advanced solid-state hydrogen storage materials (S-HSMs) for hydrogen fuel cells. The key feature for this synthesis is the use of the unique “defect” structures in carbon lattice as the efficient anchoring sites to immobilise the metal species at atomic level. This project is expected to create new knowledge of atomic interface catalysis and develop practical applications of S-HSMs in storage tanks for fuel cells, leading to reduction of carbon dioxide emissions and alleviation of air pollution. The success of this project will greatly enhance the Australian clean energy industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775511
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Laser Flash Thermophysical Properties Analyzer for the Development of Advanced Materials, Food Processing Technologies and Biomedical Components. The Australian's energy, mining, metallurgical and food industries spearhead the advancement of technologies in the global competitive market. They are the locomotive of Australian economy's strength. Future progress of these industries will be largely driven by advances in materials and food processing technology. The installation of the proposed fa ....Laser Flash Thermophysical Properties Analyzer for the Development of Advanced Materials, Food Processing Technologies and Biomedical Components. The Australian's energy, mining, metallurgical and food industries spearhead the advancement of technologies in the global competitive market. They are the locomotive of Australian economy's strength. Future progress of these industries will be largely driven by advances in materials and food processing technology. The installation of the proposed facility will add a new dimension to high-level research performance and significantly enhance the capability for characterization of various forms of materials, foods and biomedical components in Australia. The continual development of advanced materials and food processing technology will potentially provide a sustainable means for meeting the increasing global challenge for the industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100362
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Nanostructured metal hydrides for practical hydrogen storage applications. This project aims to synthesise nanostructured metal hydrides with particle size smaller than 5 nm. The practical applications of metal hydrides as advanced solid-state hydrogen storage materials require substantial knowledge and delicate engineering of materials on the nanoscale. Combined with controllable modification on the nanoscale, the optimised metal hydrides will enhance the performance of hydrogen storage materia ....Nanostructured metal hydrides for practical hydrogen storage applications. This project aims to synthesise nanostructured metal hydrides with particle size smaller than 5 nm. The practical applications of metal hydrides as advanced solid-state hydrogen storage materials require substantial knowledge and delicate engineering of materials on the nanoscale. Combined with controllable modification on the nanoscale, the optimised metal hydrides will enhance the performance of hydrogen storage materials. This project is expected to advance understanding of the technologies of metal hydrides as hydrogen storage materials and develop practical applications of metal hydrides in storage tanks for fuel cells. Hydrogen energy could also reduce carbon dioxide emissions and alleviate air pollution.Read moreRead less
Ion implantation processing in Silicon Carbide for microelectronic applications. The aim of this project is to study the application of ion implantation to silicon carbide for dopant incorporation and defect engineering. The successful dopant incorporation, especially p-type doping will be crucial for SiC high power and high frequency devices. The outcomes of the project are (a) the understanding of extended and point defect formation in silicon carbide from ion implantation. (b) detailed charac ....Ion implantation processing in Silicon Carbide for microelectronic applications. The aim of this project is to study the application of ion implantation to silicon carbide for dopant incorporation and defect engineering. The successful dopant incorporation, especially p-type doping will be crucial for SiC high power and high frequency devices. The outcomes of the project are (a) the understanding of extended and point defect formation in silicon carbide from ion implantation. (b) detailed characterisation of the extended defects formed by ion implantation (c) establishment of dose regimes for point defects and extended defect formation and (d) development of procedures for the incorporation of dopants with minimum residual defect formation.Read moreRead less
Investigation of contaminant distribution, deposition and poisoning of cathodes of solid oxide fuel cells. The purpose of the project is to fundamentally study the poisoning process of contaminants on the performance degradation and activity of solid oxide fuel cells (SOFC) cathode and to develop contaminant-tolerant cathodes, so as to ensure the product life over five years of the BlueGen SOFC systems being developed by Ceramic Fuel Cells Ltd. in Melbourne.
Molecular dynamic simulation and experimental study on the mechanisms of high critical current density in superconductors. The aim of this project is to establish a collaboration between the Institute for Superconducting and Electronic Materials (ISEM) and the team at Nanjing University to study the mechanisms of high critical current density (or flux pinning) in superconductors. Molecular dynamic simulation combined with experimental techniques, such as transport and magnetic measurements will ....Molecular dynamic simulation and experimental study on the mechanisms of high critical current density in superconductors. The aim of this project is to establish a collaboration between the Institute for Superconducting and Electronic Materials (ISEM) and the team at Nanjing University to study the mechanisms of high critical current density (or flux pinning) in superconductors. Molecular dynamic simulation combined with experimental techniques, such as transport and magnetic measurements will be used. The results of this work will expand our understanding of the pinning mechanisms of high temperature superconductors and MgB2 superconductors, with the hope of further enhancing the current carrying capacity, and therefore promoting the practical applications of superconductors.Read moreRead less
First-Principles Engineering of Advanced Multicomponent Materials for Clean, Energy Efficient Thermoelectric and Catalytic Technologies. The quantum mechanical, first-principles calculations for studying advanced multicomponent materials and surfaces of high current technological interest will produce significant results as well as fundamental knowledge of key mechanisms that will aid in the design and tailoring of new catalytic and thermoelectric materials. The project is directly relevant to ....First-Principles Engineering of Advanced Multicomponent Materials for Clean, Energy Efficient Thermoelectric and Catalytic Technologies. The quantum mechanical, first-principles calculations for studying advanced multicomponent materials and surfaces of high current technological interest will produce significant results as well as fundamental knowledge of key mechanisms that will aid in the design and tailoring of new catalytic and thermoelectric materials. The project is directly relevant to the designated priority area - Frontier Technologies for Building and Transforming Australian Industries. It will involve collaboration with leading international experts, thus enhancing Australia's knowledge base and research capacity. This clearly has immediate benefits through the transfer and propagation of cutting-edge knowledge and skills to students and post-docs.Read moreRead less