Development of a novel and practical method for fabricating carbon nanotube reinforced polymer composites for automotive applications. An effective, economical and environmentally friendly technology will be developed by this project to fabricate carbon nanotube reinforced polymer composites. The thus obtained products will be applied as automotive parts.
Materials Engineering Solutions for Tomorrow's Water Resources. This proposal concerns the development of advanced technologies informed by knowledge management systems to ensure the continued provision of high-quality drinking water to Australian. This is particularly important as we see the impacts from climate change and extreme weather variability with catastrophic consequences such as recently seen in Victoria and in Queensland on water catchments and water quality and supply. The challenge ....Materials Engineering Solutions for Tomorrow's Water Resources. This proposal concerns the development of advanced technologies informed by knowledge management systems to ensure the continued provision of high-quality drinking water to Australian. This is particularly important as we see the impacts from climate change and extreme weather variability with catastrophic consequences such as recently seen in Victoria and in Queensland on water catchments and water quality and supply. The challenges of adequate water resourcing, both in quantity and quality, for Australians who wish to lead healthy and productive lives are serious and require collaboration between industry, government and research providers such as is proposed here. Read moreRead less
It’s a fine line: analytical and experimental optimisation of drawing metal-in-dielectric nanowire composites to manufacture engineered metamaterials. Exploitation of ‘smart materials’ is a major opportunity for 21st century Australian manufacturing if cost effective bulk production is available. Metamaterials are ideal building blocks for such new-age materials, being dielectric/metal composites structured on sub-wavelength dimensions, offering diverse properties unavailable in natural material ....It’s a fine line: analytical and experimental optimisation of drawing metal-in-dielectric nanowire composites to manufacture engineered metamaterials. Exploitation of ‘smart materials’ is a major opportunity for 21st century Australian manufacturing if cost effective bulk production is available. Metamaterials are ideal building blocks for such new-age materials, being dielectric/metal composites structured on sub-wavelength dimensions, offering diverse properties unavailable in natural materials. Fibre drawing is a proven mass-production technology for translating the structure of a (macroscale) preform to microscale and has recently been applied it to fabricate microscale metamaterials. By overcoming fundamental instabilities, this project will transform the technique to manufacture nanoscale structured composites and demonstrate practical metamaterial-based optical devices with unique properties.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102664
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A micro-compression study of aluminium alloys: establishing the nanoscale mechanisms of precipitate-induced strengthening to achieve stronger alloys. This project will study the strengthening mechanisms of aluminium alloys by directly observing how dislocations interact with solute nanostructures. The research will advance our knowledge of dislocation dynamics in precipitation-strengthening alloys, and provide a quantitative method for controlling those nanostructures to achieve higher strength ....A micro-compression study of aluminium alloys: establishing the nanoscale mechanisms of precipitate-induced strengthening to achieve stronger alloys. This project will study the strengthening mechanisms of aluminium alloys by directly observing how dislocations interact with solute nanostructures. The research will advance our knowledge of dislocation dynamics in precipitation-strengthening alloys, and provide a quantitative method for controlling those nanostructures to achieve higher strength alloys.Read moreRead less