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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100070
Funder
Australian Research Council
Funding Amount
$241,500.00
Summary
Automated Fibre Braiding Facility for Multifunctional Structural Materials. Automated fibre braiding facility for multifunctional structural materials:
This project seeks to establish an Australian automated braiding facility to create innovative fibrous materials with multiple functionalities. This facility aims to provide Australian researchers with the capabilities of high-speed, precision and versatility to radially braid single or multiple filament types including carbon, metal, optical, n ....Automated Fibre Braiding Facility for Multifunctional Structural Materials. Automated fibre braiding facility for multifunctional structural materials:
This project seeks to establish an Australian automated braiding facility to create innovative fibrous materials with multiple functionalities. This facility aims to provide Australian researchers with the capabilities of high-speed, precision and versatility to radially braid single or multiple filament types including carbon, metal, optical, natural, bio-inspired and bio-compatible fibres and filaments to create new materials with unique functional properties. The facility would be able to braid over multiple length scales spanning nanofibres to millimetre-sized filaments to create novel materials and shapes not possible using other processing techniques. Expected applications include new materials for building, self-healing, human protection and biomedicine. Read moreRead less
The plasma boundary: a major challenge for fusion science and material technology for ITER and beyond. Plasma-surface interaction drives technological innovation in areas of nanofabrication, space science and magnetic fusion systems. This interdisciplinary research project will foster national and international collaborations, keeping Australia internationally competitive in, and at the forefront of, future technologies for energy and materials.
Ultrafine grained titanium for bio-implant applications. The project underpins the potential niche applications of ultrafine grained titanium for biomedical implants and establishes a knowledge base for expanding Australia's capacity for manufacturing titanium parts. The novel technology will lead to a broader usage of titanium by biomedical industry and promote the development of the titanium manufacturing industry in Australia. The development of ultrafine grained titanium specifically designe ....Ultrafine grained titanium for bio-implant applications. The project underpins the potential niche applications of ultrafine grained titanium for biomedical implants and establishes a knowledge base for expanding Australia's capacity for manufacturing titanium parts. The novel technology will lead to a broader usage of titanium by biomedical industry and promote the development of the titanium manufacturing industry in Australia. The development of ultrafine grained titanium specifically designed for bio-implants will increase Australia's competitiveness in the global market. The project targets at least three of the priority goals specified under National Research Priority breakthrough science, frontier technologies and advanced materials.Read moreRead less
Exploiting deep sub-surface temperature-induced phase-transformations for an improved approach to semiconductor laser-dicing. This project aims to explore sub-surface laser-induced phase transformations in semiconductors and to exploit this novel method for ultra-fine laser cutting of semiconductor wafers without debris. The outcomes will be understanding new temperature-induced material modifications and innovative technology development relevant for the semiconductor industry.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100028
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Advanced surface imaging and spectroscopy facility: Scanning auger nanoprobe. Understanding advanced materials and nano-fabricated devices on the nanometre scale is essential for innovation in the manufacturing, healthcare, pharmaceutical, energy and mining sectors. The next generation Scanning Auger Nanoprobe will support research rated well-above world standard and dramatically increase national surface analytical capacity.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100141
Funder
Australian Research Council
Funding Amount
$1,294,000.00
Summary
Facility for in-situ nuclear magnetic resonance of advanced materials and devices. This unique characterisation facility will support and enhance high-quality research in four key areas: electro-materials and nanotechnology, light metal alloys, biotechnology and energy related devices. This research will lead to new materials and new technologies in clean energy, carbon dioxide capture and health care.
Synthesis of novel phases from Group IV elements under extreme pressure. Materials based on the group IV elements carbon, silicon and germanium are technologically important for a wide range of current applications. When exposed to extreme pressure, these materials can form entirely new phases with novel and potentially useful properties. Since there have been few previous attempts to establish which of the new phases are stable on pressure release and to measure their properties for subsequent ....Synthesis of novel phases from Group IV elements under extreme pressure. Materials based on the group IV elements carbon, silicon and germanium are technologically important for a wide range of current applications. When exposed to extreme pressure, these materials can form entirely new phases with novel and potentially useful properties. Since there have been few previous attempts to establish which of the new phases are stable on pressure release and to measure their properties for subsequent exploitation, this project aims to use novel approaches to address these topics. The expected outcome of this project will be new phases of group IV elements with novel properties that have potential for commercial exploitation.Read moreRead less