Industrial Transformation Research Hubs - Grant ID: IH150100024
Funder
Australian Research Council
Funding Amount
$2,799,251.00
Summary
ARC Research Hub for Advanced Manufacturing of Medical Devices. ARC Research Hub for Advanced Manufacturing of Personalised Medical Devices. The project aims to transform Australia’s $10.8 billion medical technology sector by developing cost competitive technologies for the rapid production of personalised devices for Endovascular Aneurysm Repair (EVAR). To ensure the Australian industry remains globally competitive, this hub seeks to concurrently develop materials, technologies and flexible man ....ARC Research Hub for Advanced Manufacturing of Medical Devices. ARC Research Hub for Advanced Manufacturing of Personalised Medical Devices. The project aims to transform Australia’s $10.8 billion medical technology sector by developing cost competitive technologies for the rapid production of personalised devices for Endovascular Aneurysm Repair (EVAR). To ensure the Australian industry remains globally competitive, this hub seeks to concurrently develop materials, technologies and flexible manufacturing processes. The intended research outcomes include more efficient design and manufacturing processes and a new range of EVAR products generating increased market share and higher workforce capability. The resulting impacts should be better health outcomes, job creation and providing SMEs with new technologies and skills that can be transferred to the manufacture of products for other sectors.Read moreRead less
A new in-situ structural measurement capability during nanoindentation. A new in-situ structural measurement capability during nanoindentation. This project aims to develop an in-situ Raman capability to obtain dynamic structural and mechanical behaviour of materials as a function of pressure during nanoindentation; and apply the new capability to directly monitor phase changes in silicon and germanium under pressure and correlate them with the simultaneous electrical responses. Anticipated outc ....A new in-situ structural measurement capability during nanoindentation. A new in-situ structural measurement capability during nanoindentation. This project aims to develop an in-situ Raman capability to obtain dynamic structural and mechanical behaviour of materials as a function of pressure during nanoindentation; and apply the new capability to directly monitor phase changes in silicon and germanium under pressure and correlate them with the simultaneous electrical responses. Anticipated outcomes are new instrumentation to directly probe the pressure-temperature phase diagram, and measure electrical properties of novel end phases in these semiconductors.Read moreRead less
High energy density, long life, safe lithium Ion battery for electric cars. This project aims to develop next-generation lithium-ion batteries with high energy density, safety, long cycle life, and fast charge capability, using a Ni-rich layered oxide cathode and silicon/carbon composite anode. This lithium-ion battery system is expected to meet 2020 targets for electric vehicles. The project will also investigate the reaction/electrode fading mechanism of the proposed anode/cathode materials fo ....High energy density, long life, safe lithium Ion battery for electric cars. This project aims to develop next-generation lithium-ion batteries with high energy density, safety, long cycle life, and fast charge capability, using a Ni-rich layered oxide cathode and silicon/carbon composite anode. This lithium-ion battery system is expected to meet 2020 targets for electric vehicles. The project will also investigate the reaction/electrode fading mechanism of the proposed anode/cathode materials for the deep understanding of these electrode materials, and provide guidance for future electrode materials design and battery research. This will provide significant benefits for automotive industries, smart grid, and business in storing renewable energy and better environment and sustainability.Read moreRead less
Diamond Microneedles for Minimally Invasive Blood Collection. Blood sampling is a routine procedure for medical purposes to determine the physiological and biochemical status of patients. The aim of this project is to develop a reliable microneedle array for a blood collection procedures. Micro-scale needles for low-volume perforated blood samples are highly desirable due to its minimal invasiveness and painlessness. The miniaturization of sampling platforms driven by microneedles has the poten ....Diamond Microneedles for Minimally Invasive Blood Collection. Blood sampling is a routine procedure for medical purposes to determine the physiological and biochemical status of patients. The aim of this project is to develop a reliable microneedle array for a blood collection procedures. Micro-scale needles for low-volume perforated blood samples are highly desirable due to its minimal invasiveness and painlessness. The miniaturization of sampling platforms driven by microneedles has the potential to shift disease diagnosis and monitoring closer to the point of care. Expected outcomes include the development of synthetic diamond-based microneedles for the potential to greatly benefit society through improved and affordable healthcare and the development of new high-tech industries.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL190100139
Funder
Australian Research Council
Funding Amount
$3,185,850.00
Summary
New Artificial Leaf for Efficient Solar Fuel Production . The Fellowship aims to develop next-generation materials that harness solar energy to produce valuable fuels and chemicals from water and carbon dioxide, replacing fossil fuels. The program will design new semiconductor materials to revolutionise solar-to-fuel technologies that currently have very low efficiency. The expected outcomes include innovative systems such as wireless artificial leaves that mimic natural photosynthesis for effic ....New Artificial Leaf for Efficient Solar Fuel Production . The Fellowship aims to develop next-generation materials that harness solar energy to produce valuable fuels and chemicals from water and carbon dioxide, replacing fossil fuels. The program will design new semiconductor materials to revolutionise solar-to-fuel technologies that currently have very low efficiency. The expected outcomes include innovative systems such as wireless artificial leaves that mimic natural photosynthesis for efficient hydrocarbon production, carbon dioxide reduction, and water purification. The expected benefits include next-generation solar fuel and chemical generation technologies, and research capabilities to position Australia as a global leader in the transition to a decarbonised economy.Read moreRead less
Fundamentals of Electrically Conductive Elastomer Composites. This project aims to address the performance instability of stretchable/flexible electronics and devices, by developing mechanically resilient, electrically conductive patterns of nanomaterials to be encased in elastomers. It expects to generate new knowledge in the field of composite processing, to provide fundamentals for composite industry to develop novel strain gauges and conductors. Expected outcomes include a methodology for st ....Fundamentals of Electrically Conductive Elastomer Composites. This project aims to address the performance instability of stretchable/flexible electronics and devices, by developing mechanically resilient, electrically conductive patterns of nanomaterials to be encased in elastomers. It expects to generate new knowledge in the field of composite processing, to provide fundamentals for composite industry to develop novel strain gauges and conductors. Expected outcomes include a methodology for stabilising the cyclic performance of electrically conductive elastomer composites. This project is anticipated to provide significant long-term benefits not only for underwater infrastructure condition monitoring but for remote and personalised health-monitoring.Read moreRead less
Lithium-rich cathode materials for high-energy lithium-ion batteries. This project aims to develop lithium-rich cathode materials for a new generation of high-energy lithium-ion batteries. These innovative materials could double the capacity of commercial cathodes, thereby doubling the energy density of lithium-ion batteries. A further increase is anticipated from fundamental insights into anionic redox. Expected outcomes include materials with optimised architecture and chemistry, stabilisation ....Lithium-rich cathode materials for high-energy lithium-ion batteries. This project aims to develop lithium-rich cathode materials for a new generation of high-energy lithium-ion batteries. These innovative materials could double the capacity of commercial cathodes, thereby doubling the energy density of lithium-ion batteries. A further increase is anticipated from fundamental insights into anionic redox. Expected outcomes include materials with optimised architecture and chemistry, stabilisation of lithium-rich cathodes, identification of redox mechanism of lithium-rich cathode materials, technologies for producing lithium-rich cathode materials on a large scale and fabrication of new generation high-energy lithium-ion batteries. This project will have benefits especially in the transport and energy sectors. Read moreRead less
Pattern formation of precursor films: a new mathematical model. This project aims to develop a new mathematical model to predict the pattern formation of a new class of permanent lubricants. Ionic liquids are conductive and do not evaporate, creating a unique opportunity to develop such coatings. These thin films form patterns where the pattern type (patches, stripes or holes) depends on the liquid/surface interaction. Only some patterns result in good lubrication; current limited understanding ....Pattern formation of precursor films: a new mathematical model. This project aims to develop a new mathematical model to predict the pattern formation of a new class of permanent lubricants. Ionic liquids are conductive and do not evaporate, creating a unique opportunity to develop such coatings. These thin films form patterns where the pattern type (patches, stripes or holes) depends on the liquid/surface interaction. Only some patterns result in good lubrication; current limited understanding of the pattern formation process hampers selection of a good lubricant for a chosen material. Current mathematical approaches are computationally expensive and time consuming. The new model expected from this project would provide a cheap, fast and reliable alternative for screening suitable liquid/surface pairs.Read moreRead less
Novel hydrogen-rich liquids for storing and transporting hydrogen at scale. Hydrogen is proposed as the best candidate to store large amounts of energy produced by intermittent sources such as wind and solar. This project aims to address challenges in storing and transporting large amounts of hydrogen in a safe and effective way by developing novel liquid-phase compounds that contain light elements including boron, carbon, nitrogen, and hydrogen. Expected outcomes of this project include new liq ....Novel hydrogen-rich liquids for storing and transporting hydrogen at scale. Hydrogen is proposed as the best candidate to store large amounts of energy produced by intermittent sources such as wind and solar. This project aims to address challenges in storing and transporting large amounts of hydrogen in a safe and effective way by developing novel liquid-phase compounds that contain light elements including boron, carbon, nitrogen, and hydrogen. Expected outcomes of this project include new liquid compounds that can effectively and safely store hydrogen at scale using the exisiting liquid hydrocarbon fuel infrastructure. This should provide significant benefits in the establishment of renewable hydrogen for domestic consumption and more for exporting sustainable and clean fuel using hydrogen as the energy carrier.Read moreRead less