Low-temperature plasma processes for high-quality graphene films. The project aims to develop novel plasma-enabled processes for low-cost, energy-efficient, and scalable growth of high-quality graphene films for applications in touch screen, solar cell and other devices. It aims to discover non-equilibrium plasma-surface interactions enabling nucleation and growth of graphene films with large and low-defect domains on metal catalysts at low temperatures, and then develop energy-efficient, enviro ....Low-temperature plasma processes for high-quality graphene films. The project aims to develop novel plasma-enabled processes for low-cost, energy-efficient, and scalable growth of high-quality graphene films for applications in touch screen, solar cell and other devices. It aims to discover non-equilibrium plasma-surface interactions enabling nucleation and growth of graphene films with large and low-defect domains on metal catalysts at low temperatures, and then develop energy-efficient, environment-friendly, and scalable fabrication and device transfer processes. These processes are designed to retain high quality of graphene films upon scale-up and will be compatible with the existing and emerging applications in touch screens and other devices. The expected outcomes include fundamental understanding and novel practical approaches to control synthesis and device integration of two-dimensional atomically-thin materials.Read moreRead less
Understanding of nanostructures and magnetic properties of Ge-based diluted magnetic semiconductors for spintronic devices. The success of growing high-quality germanium-based diluted magnetic semiconductors will position Australian fundamental & applied research at the world forefront of magnetic semiconductors. This multi-disciplinary research will not only secure a number of high-impact publications in leading international journals, but also has the potential to generate patentable technolog ....Understanding of nanostructures and magnetic properties of Ge-based diluted magnetic semiconductors for spintronic devices. The success of growing high-quality germanium-based diluted magnetic semiconductors will position Australian fundamental & applied research at the world forefront of magnetic semiconductors. This multi-disciplinary research will not only secure a number of high-impact publications in leading international journals, but also has the potential to generate patentable technologies which might bring potential economic benefits to Australia. In addition, the project will strengthen the collaboration between Australian researchers and world-renowned scientists and will allow Australian researchers to access world-best fabrication facilities. All these will enhance the international competitive profile of Australia in the field of spintronics.Read moreRead less
Design of new two-dimensional materials for lithium sulphur batteries. Design of new two-dimensional materials for lithium sulphur batteries. This project aims to develop classes of electrode material systems for high performance batteries. This project will design new hierarchical cathode composites for a high capacity lithium-sulphur battery with a long cycling life. It intends to improve energy density by confining active sulphur in conductive graphene and exfoliated titanium dioxide nanoshee ....Design of new two-dimensional materials for lithium sulphur batteries. Design of new two-dimensional materials for lithium sulphur batteries. This project aims to develop classes of electrode material systems for high performance batteries. This project will design new hierarchical cathode composites for a high capacity lithium-sulphur battery with a long cycling life. It intends to improve energy density by confining active sulphur in conductive graphene and exfoliated titanium dioxide nanosheets, and use a unique hybrid protecting layer to suppress cycling instability. This research is expected to establish the relationship between synthetic conditions, structure, and electrochemical performance.Read moreRead less
Designs of Periodic Microstructure Materials with Prescribed Multiphysical Properties. The evolutionary structural optimization (ESO) is an Australian initiative, which has made a significant impact on modern structural optimization. In advanced materials areas, Australia has well-established infrastructure and world-class expertise. Exploitation of ESO to advanced materials design will be of "exclusive significance" to Australia. More importantly, the new material design technology will present ....Designs of Periodic Microstructure Materials with Prescribed Multiphysical Properties. The evolutionary structural optimization (ESO) is an Australian initiative, which has made a significant impact on modern structural optimization. In advanced materials areas, Australia has well-established infrastructure and world-class expertise. Exploitation of ESO to advanced materials design will be of "exclusive significance" to Australia. More importantly, the new material design technology will present to Australia an opportunity to lead in this rapidly-growing area, which will definitely underpin Australia's standing as a major contributor and developer in a global materials market. It is expected that fresh classes of futuristic materials can be developed in a cost-effective fashion and add great economic benefits to Australia.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC160100036
Funder
Australian Research Council
Funding Amount
$4,881,754.00
Summary
ARC Training Centre in Alloy Innovation for Mining Efficiency. ARC Training Centre in Alloy Innovation for Mining Efficiency. This centre aims to make Australian manufacturers dominant in the multi-billion dollar mining equipment sector by training innovators to design the world’s best highly customized long-life, wear resistant components. It intends to rapidly develop customized alloys that excel in severe mining conditions, using three-dimensional printing, novel characterisation and its netw ....ARC Training Centre in Alloy Innovation for Mining Efficiency. ARC Training Centre in Alloy Innovation for Mining Efficiency. This centre aims to make Australian manufacturers dominant in the multi-billion dollar mining equipment sector by training innovators to design the world’s best highly customized long-life, wear resistant components. It intends to rapidly develop customized alloys that excel in severe mining conditions, using three-dimensional printing, novel characterisation and its networked training environment. It expects these innovations will enable much needed efficiencies after the end of the mining super-cycle. Anticipated outcomes are the design of products with superior alloy design and material selection; jobs growth and security in the mining component production sector; and increased mining efficiency and cost reduction.Read moreRead less
Epitaxial growth of Zn-VI/III-N nanowire-based structures for future device applications. This project, aiming for developing zinc and nitrogen epitaxial nanowires, addresses specific National Research Priorities in the areas of breakthrough science, frontier technology and advanced materials. Outcomes will significantly advance the understanding of the evolution of epitaxial nanowire structures and their demonstrated properties. This project will provide informative guidelines for designing, de ....Epitaxial growth of Zn-VI/III-N nanowire-based structures for future device applications. This project, aiming for developing zinc and nitrogen epitaxial nanowires, addresses specific National Research Priorities in the areas of breakthrough science, frontier technology and advanced materials. Outcomes will significantly advance the understanding of the evolution of epitaxial nanowire structures and their demonstrated properties. This project will provide informative guidelines for designing, developing and manufacturing nanowire-based nanostructures for future nanodevices and nanosystems, which is strategically important to Australia's emerging high-tech industries. This project will also enhance the international reputation and impact of Australian research in the internationally focused field of nanoscience and nanotechnology.Read moreRead less
Development of next generation smart sucker rod wear guides . In a natural gas wells, sucker rod guides protect the production tubing from wear by the rod string. Premature and erratic failures are costing the industry tens of millions every year. In collaboration with two local SMEs, this project aims to develop the next generation of smart and durable wear guides. The project seeks to understand the complex three body wear mechanisms that drive guide and tubing wear, then use this knowledge to ....Development of next generation smart sucker rod wear guides . In a natural gas wells, sucker rod guides protect the production tubing from wear by the rod string. Premature and erratic failures are costing the industry tens of millions every year. In collaboration with two local SMEs, this project aims to develop the next generation of smart and durable wear guides. The project seeks to understand the complex three body wear mechanisms that drive guide and tubing wear, then use this knowledge to develop new wear resistant compounds and develop a smart guide that provides feedback on its wear state. This will enable the industry partners to supply cutting edge technology to the global oil and gas industry that not only reduces well operation cost but also enhances well resilience.Read moreRead less
Understanding the role of catalysts in the growth of epitaxial semiconductor nanowires and their hierarchical heterostructures. This Fellowship aims to comprehensively determine the role of catalysts during nanowire growth, solving the bottle-neck problem for growing device-applicable nanowires. In order to address this complicated scientific challenge, the project plans to collaborate with several world-leading researchers in different areas, such as growth, property measurements and modelling. ....Understanding the role of catalysts in the growth of epitaxial semiconductor nanowires and their hierarchical heterostructures. This Fellowship aims to comprehensively determine the role of catalysts during nanowire growth, solving the bottle-neck problem for growing device-applicable nanowires. In order to address this complicated scientific challenge, the project plans to collaborate with several world-leading researchers in different areas, such as growth, property measurements and modelling. The outcomes of this Fellowship will not only provide new science in terms of nanowire growth, but also provide guidelines for designing, developing and manufacturing nanowire-based nanostructures for future nanodevices and nanosystems. This is strategically important to place Australia at the forefront of developments on nanoscience and nanotechnology.Read moreRead less
Surface engineering of cast magnesium alloys for innovative high performance packaging robots. High performance packaging robots are in significant demand in the food, medicine and cosmetics industries. This project will solve a critical problem in the development of such robots at low cost by the novel use of cast magnesium alloys, which will greatly increase productivity and decrease energy consumption through weight reduction.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100156
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Advanced Laser Additive Manufacturing System for Extended Applications to Surface Engineering, Direct Manufacturing and New Alloy Development. Advanced laser additive manufacturing system for extended applications to surface engineering, direct manufacturing and new alloy development: This project will provide an advanced laser additive manufacturing system for extended applications. Although the facility was originally designed for forefront additive manufacturing, it enables innovative resear ....Advanced Laser Additive Manufacturing System for Extended Applications to Surface Engineering, Direct Manufacturing and New Alloy Development. Advanced laser additive manufacturing system for extended applications to surface engineering, direct manufacturing and new alloy development: This project will provide an advanced laser additive manufacturing system for extended applications. Although the facility was originally designed for forefront additive manufacturing, it enables innovative research on surface engineering to solve the long standing corrosion and wear problems associated with metal components and to produce biomedical coatings on titanium implants. The facility can also be used to develop high quality alloys, including titanium and magnesium alloys, through an accelerated metallurgy approach, leading to breakthrough progress in metal research. Such alloys are highly desired by automotive and aerospace industries to improve fuel efficiency through weight reduction. Read moreRead less