Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100069
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A complete thermo-electric characterisation facility for exploration of novel materials and devices at high temperatures. This high temperature materials’ characterisation facility will be the most advanced measurement setup of its kind in Australia. The unique features of the equipment and its high versatility will substantially enhance national research capabilities in functional materials, metal engineering, manufacturing engineering, chemistry, and physics.
Long-term corrosion of offshore steel structures in near-stagnant seawater. This project investigates the seawater corrosion of structural steels under near-stagnant and possibly polluted conditions. Better understanding of long-term corrosion of structural steels in near-stagnant seawaters is needed to predict the safety of steel offshore structures such as the pods supporting wind and wave energy generators. Also, the expensive maintenance of protective coatings and systems could be obviated o ....Long-term corrosion of offshore steel structures in near-stagnant seawater. This project investigates the seawater corrosion of structural steels under near-stagnant and possibly polluted conditions. Better understanding of long-term corrosion of structural steels in near-stagnant seawaters is needed to predict the safety of steel offshore structures such as the pods supporting wind and wave energy generators. Also, the expensive maintenance of protective coatings and systems could be obviated or reduced if corrosion remains acceptable. This project plans to investigate experimentally the temporal development and stochastic nature of general corrosion and pitting for steels under actual near-stagnant seawater conditions. It also plans to build mathematical-probabilistic models for corrosion prediction, calibrated to field data. These models will include allowance for microbiological corrosion effects, important under anthropological pollution.Read moreRead less
Avoiding catastrophic failure of rock bolts in underground coal mines. This project will examine the factors responsible for the emerging problem of catastrophic failure of rock bolts in underground mines in order to develop strategies for resisting such failures. The consequences of rock bolt failure are potentially enormous from both a mine safety and economic standpoint. The strategies developed are expected to not only reduce the likelihood of injury and death from rock falls but to also red ....Avoiding catastrophic failure of rock bolts in underground coal mines. This project will examine the factors responsible for the emerging problem of catastrophic failure of rock bolts in underground mines in order to develop strategies for resisting such failures. The consequences of rock bolt failure are potentially enormous from both a mine safety and economic standpoint. The strategies developed are expected to not only reduce the likelihood of injury and death from rock falls but to also reduce very expensive mine downtime and avoid costly replacement of broken rock bolts. Australian Rock Bolting Technology is now used internationally and the work will be of substantial significance both nationally and internationally. It will help maintain Australia's international prominence in this field.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102778
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Enabling a new generation of advanced high-strength aluminium alloys through materials design. This project will create an analysis-engine of novel atom-sensitive methods to unlock the materials science of hierarchy-strengthening. It will assist in determining how hierarchical structures evolve and synergistically strengthen a new generation of advanced high-strength aluminium alloys that are strong as steel, but a third the weight.
Discovery Early Career Researcher Award - Grant ID: DE140100188
Funder
Australian Research Council
Funding Amount
$390,572.00
Summary
Understanding failure mechanisms in micro-solder joints in three dimensional integrated circuit packaging. High-density three-dimensional integrated circuits used in microelectronic devices are evolving and placing increasing demands on micro-solder joints. Tin based lead-free solder alloys require further development to satisfy performance requirements, particularly with respect to the properties of the intermetallic forms between solder and substrate. This project investigates the mechanical p ....Understanding failure mechanisms in micro-solder joints in three dimensional integrated circuit packaging. High-density three-dimensional integrated circuits used in microelectronic devices are evolving and placing increasing demands on micro-solder joints. Tin based lead-free solder alloys require further development to satisfy performance requirements, particularly with respect to the properties of the intermetallic forms between solder and substrate. This project investigates the mechanical properties and deformation mechanisms of intermetallic forms with trace element additions using micro-pillar compression and ultra-high voltage transmission electron microscopy. Beyond the development of techniques transferable to similar research, this project will lead to significant intellectual property relating to solder composition.Read moreRead less
Atomic scale information for the design of nanomaterials. This project aims to develop a new tool to measure the 3-D distribution of atoms within nanoparticles. For the rational design of nanoparticles, it is necessary to compare the atomic scale structure to the resulting performance. But this information is hard to access. This projects aims to develop new methods so that atom probe microscopy can be applied to experimentally measure the precise 3-D location and identity of the individual atom ....Atomic scale information for the design of nanomaterials. This project aims to develop a new tool to measure the 3-D distribution of atoms within nanoparticles. For the rational design of nanoparticles, it is necessary to compare the atomic scale structure to the resulting performance. But this information is hard to access. This projects aims to develop new methods so that atom probe microscopy can be applied to experimentally measure the precise 3-D location and identity of the individual atoms within nanoparticles, and apply them in the development of alloy catalyst nanoparticles that could make the sustainable production of liquid fuels from biomass commercially viable. These new tools would be useful across the wide range of engineering applications for which nanomaterials are currently being developed.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100059
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Vacuum induction furnace for casting titanium alloys. This titanium melting facility will provide a level of investment and national strategic focus necessary to sustain Australian competitive advantage in both titanium research and the global titanium market. The facility will support cutting-edge research and support the development of new titanium products.
Plastic deformation and failure of high strength rail steels in heavy haul transportation of mineral products. The Australian Government has made infrastructure, including rail, as a national priority for investment to meet the freight transport demand. This project focuses on the deformation and failure of rail in heavy haul lines to transport ores in the mining industry. The outcomes will be applied to ensure the structural integrity of rail infrastructure.
Discovery Early Career Researcher Award - Grant ID: DE130100310
Funder
Australian Research Council
Funding Amount
$373,850.00
Summary
Nano-engineered, cost-effective lead chalcogenides to boost the performance of mid-range temperature thermoelectric materials. This project presents high performance, cost-effective lead-based thermoelectric materials for mid-range temperature thermoelectric generators. The development of these materials for waste heat recovery and solar thermoelectric generators will bring tremendous economic benefits and can have a profound impact on clean alternative energy sources.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100094
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Selective laser melting - an advanced manufacturing and physical modelling technology for the digital age. Selective laser melting is a new manufacturing technology that creates parts layer by layer directly from a computer model, eliminating the need for tooling or machining. This technology will be applied to a diverse range of research areas from producing the next generation of medical implants and devices to improving our understanding of geo-materials.