Carbon nanotube fluidic channels for desalination - interplay of nanoscale confinement and electrostatics. Tiny tubes of carbon, ten thousand times smaller than human hair, allow water to pass through at extraordinary speed. This project aims to understand and improve their salt rejection properties using comprehensive experimental and theoretical approaches. This will provide the impetus and knowledge for developing advanced membranes for desalination
Electrically conductive elastomeric composites by nanomaterials. Electrically conductive elastomeric composites by nanomaterials. This project aims to develop electrically conductive, mechanically robust, cost-effective elastomeric composites, by exploring new processing methods and studying the synergy between graphene sheets and multi-walled carbon nanotubes. Composites will be design, research and manufactured to suit the fabrication of rolling-resistance sensors that detect early-stage malfu ....Electrically conductive elastomeric composites by nanomaterials. Electrically conductive elastomeric composites by nanomaterials. This project aims to develop electrically conductive, mechanically robust, cost-effective elastomeric composites, by exploring new processing methods and studying the synergy between graphene sheets and multi-walled carbon nanotubes. Composites will be design, research and manufactured to suit the fabrication of rolling-resistance sensors that detect early-stage malfunctioning idler rolls. This technology could prevent the breakage of conveyor belts which are essential to the mining, processing and transportation of loose bulk materials; and improve the design and manufacturing of flexible sensors.Read moreRead less
Defect engineering in molecular beam epitaxy-grown mercury cadmium telluride. This project aims to develop high quality mercury cadmium telluride (HgCdTe) materials with lower defect density and lower background doping levels. This will enable future, high-performance, lower-cost infrared sensors with the unique features of higher yield, larger array size and higher operating temperature. The project will generate new science and technologies on defect engineering in the epitaxial growth of sem ....Defect engineering in molecular beam epitaxy-grown mercury cadmium telluride. This project aims to develop high quality mercury cadmium telluride (HgCdTe) materials with lower defect density and lower background doping levels. This will enable future, high-performance, lower-cost infrared sensors with the unique features of higher yield, larger array size and higher operating temperature. The project will generate new science and technologies on defect engineering in the epitaxial growth of semiconducting HgCdTe on cadmium zinc telluride (CdZnTe) substrates. This will contribute to the development of core Australian industry sectors such as defence, environmental monitoring, medical imaging, earth remote sensing, mining, and oil and gas.Read moreRead less
Bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates. This project aims to develop bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates to enable high performance lower-cost infrared sensors with high yield, large array size, multiband detection and higher operating temperature. High performance infrared sensors and systems are core enabling technologies in civilian and defence application ....Bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates. This project aims to develop bandgap engineered mercury cadmium telluride heterostructures on gallium antimonide alternative substrates to enable high performance lower-cost infrared sensors with high yield, large array size, multiband detection and higher operating temperature. High performance infrared sensors and systems are core enabling technologies in civilian and defence applications such as remote sensing, environmental monitoring, night vision and national security. This project expects to research into defect generation mechanisms in epitaxial growth of semiconducting mercury cadmium telluride on lattice mismatched substrates. This is expected to contribute to Australian industry sectors, thereby benefiting the Australian economy, society, environment, and national security.Read moreRead less
HgCdSe: A novel II-VI semiconductor material for next generation infrared technologies. High performance infrared sensors and systems represent core technologies in various civilian and defence applications such as remote sensing, environment monitoring, night vision and national security. The goal of this project is to develop new mercury cadmium selenide-based materials on gallium antimonide substrates for future high performance infrared sensors with the unique features of low cost, large arr ....HgCdSe: A novel II-VI semiconductor material for next generation infrared technologies. High performance infrared sensors and systems represent core technologies in various civilian and defence applications such as remote sensing, environment monitoring, night vision and national security. The goal of this project is to develop new mercury cadmium selenide-based materials on gallium antimonide substrates for future high performance infrared sensors with the unique features of low cost, large array size, room temperature operation as well as multiband detection. The outcomes of this project will lead to new science and next generation infrared sensors of benefit to Australian industry and defence technology. Read moreRead less
Selective laser melting of bulk metallic glasses. The application of metallic glasses is limited due to their difficulty in producing normal sized, complex components. This project will use the unique benefits of an advance manufacturing technology called Selective Laser Melting and the theories of polymer processing, to overcome the inherent difficulties in manufacturing these materials.
Defect generation in hetero-epitaxy on lattice mismatched substrates. High quality lattice mismatched semiconductor heterostructures are core enabling technologies for next generation electronic and optoelectronic devices with new functions and features such as monolithic integration, lower production costs, larger wafer size, and better system robustness. This project will generate new science on defect generation in lattice mismatched hetero-epitaxy with the aim of developing novel strategies ....Defect generation in hetero-epitaxy on lattice mismatched substrates. High quality lattice mismatched semiconductor heterostructures are core enabling technologies for next generation electronic and optoelectronic devices with new functions and features such as monolithic integration, lower production costs, larger wafer size, and better system robustness. This project will generate new science on defect generation in lattice mismatched hetero-epitaxy with the aim of developing novel strategies for their minimisation. The direct outcome will be higher quality HgCdTe materials on lattice mismatched Si or III-V substrates with defect density low enough for fabricating high performance mid-wave and long-wave infrared arrays with features of lower cost, larger array format size, and higher operating temperature.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH140100018
Funder
Australian Research Council
Funding Amount
$4,711,583.00
Summary
ARC Research Hub for a World-class Future Fibre Industry. ARC Research Hub for a World-class Future Fibre Industry. This research hub aims to transform the Australian fibre industry into a dynamic sector focused on high-performance and high-value fibres and fibre-based products. Capitalising on the research team's combined strength in fibre science and technology, and working with highly innovative small and medium enterprises and international research leaders, the hub seeks to develop advance ....ARC Research Hub for a World-class Future Fibre Industry. ARC Research Hub for a World-class Future Fibre Industry. This research hub aims to transform the Australian fibre industry into a dynamic sector focused on high-performance and high-value fibres and fibre-based products. Capitalising on the research team's combined strength in fibre science and technology, and working with highly innovative small and medium enterprises and international research leaders, the hub seeks to develop advanced carbon fibres, nanofibres and high-performance novel fibres, as well as value-added applications of fibre materials. These materials are expected to help to reduce energy costs, minimise the environmental footprint of manufacturing processes and improve public health and safety. The hub will also train the next generation of industry-savvy fibre research leaders.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100200
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Advanced facility for magneto-transport characterisation of semiconductor nanostructures. This facility combines a 16 Tesla superconducting magnet with temperature variability from 1.5 degrees above absolute zero to 500 degrees with advanced mobility spectrum analysis algorithms. It will enable improved separation of previously indistinguishable multiple carrier effects in advanced semiconductor systems. This improved separation will allow an improved understanding of multiple carrier effects wh ....Advanced facility for magneto-transport characterisation of semiconductor nanostructures. This facility combines a 16 Tesla superconducting magnet with temperature variability from 1.5 degrees above absolute zero to 500 degrees with advanced mobility spectrum analysis algorithms. It will enable improved separation of previously indistinguishable multiple carrier effects in advanced semiconductor systems. This improved separation will allow an improved understanding of multiple carrier effects which will be essential before the development of frontier semiconductor technologies becomes possible.Read moreRead less