Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346822
Funder
Australian Research Council
Funding Amount
$538,000.00
Summary
Polymer Optical Fibre Drawing Facility. A revolutionary new technology is emerging in polymer optical fibres, sparked by an important breakthrough in polymer optical fibres that was achieved last year by researchers at the University of Sydney. Therefore, Australia currently has a unique and short-lived opportunity to firmly establish themselves as the world leaders of this technology, provided the infrastructure to realise the novel concepts is available. We request funding for a high-quality p ....Polymer Optical Fibre Drawing Facility. A revolutionary new technology is emerging in polymer optical fibres, sparked by an important breakthrough in polymer optical fibres that was achieved last year by researchers at the University of Sydney. Therefore, Australia currently has a unique and short-lived opportunity to firmly establish themselves as the world leaders of this technology, provided the infrastructure to realise the novel concepts is available. We request funding for a high-quality polymer optical fibre draw tower to enable this. The collaborating institutions will be fabricating a range of different polymer optical fibres, targeting specific applications in optical sensing and telecommunications.Read moreRead less
Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturat ....Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturation of the sector which is dominated by component companies. This system for underwater surveillance is obviously important to a country with a large coastline to defend. This project will build Australia's global reputation renowned for research excellence in fibre and fibre devices.Read moreRead less
Multi-resolution phase measuring profilometry for dynamic 3D digital imaging. Fast 3-D sensing is a key technology in many industrial application areas such as manufacturing, medical instrumentation, security systems and multimedia entertainment systems. The proposed project aims to develop a superior solution when compared to existing methods. Successful completion of this project will place Australia at the forefront in terms of this enabling technology as well establishing cutting edge exper ....Multi-resolution phase measuring profilometry for dynamic 3D digital imaging. Fast 3-D sensing is a key technology in many industrial application areas such as manufacturing, medical instrumentation, security systems and multimedia entertainment systems. The proposed project aims to develop a superior solution when compared to existing methods. Successful completion of this project will place Australia at the forefront in terms of this enabling technology as well establishing cutting edge expertise. This will potentially lead to significant commercial opportunities that can easily translate into new employment/manufacturing opportunities.Read moreRead less
New multiplexed optical read-out technologies for micromachined cantilever sensor arrays. Passive sensing of chemical and biological agents is an essential capability in fields as diverse as national security, agriculture, mining and medicine. In many cases, generic sensing (e.g. are there pesticides present) as well as specific sensing (which pesticide) are both important. While sensors based on micro-electromechanical systems (MEMS) have shown extremely high performance at low cost, they have ....New multiplexed optical read-out technologies for micromachined cantilever sensor arrays. Passive sensing of chemical and biological agents is an essential capability in fields as diverse as national security, agriculture, mining and medicine. In many cases, generic sensing (e.g. are there pesticides present) as well as specific sensing (which pesticide) are both important. While sensors based on micro-electromechanical systems (MEMS) have shown extremely high performance at low cost, they have been limited to detection of a specific substance. Success in this project will make low cost generic MEMS-based sensors a reality, allowing, for the first time, wide-spread use of sensitive sensing systems in applications such as farming, container transport security, general medical practice and national security.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL160100032
Funder
Australian Research Council
Funding Amount
$2,527,475.00
Summary
Ultralow latency wireless systems. Ultralow latency wireless systems. This project aims to develop theories and practical methods to design wireless communication systems for future generations of internet services. Emerging smart environments and infrastructure could solve major problems facing the world today, by saving energy, reducing pollution, improving health and increasing road safety. However, scientists to date do not know how to build wireless networks with almost zero latency and ult ....Ultralow latency wireless systems. Ultralow latency wireless systems. This project aims to develop theories and practical methods to design wireless communication systems for future generations of internet services. Emerging smart environments and infrastructure could solve major problems facing the world today, by saving energy, reducing pollution, improving health and increasing road safety. However, scientists to date do not know how to build wireless networks with almost zero latency and ultrahigh reliability, needed for machine-to-machine communications. An expected outcome of this project is new criteria and methodologies to design such wireless systems, which would affect future wireless systems and grids.Read moreRead less
Advanced Laser, Sensor and Diagnostic Technologies Using New Generation Micro- and Nano- Structured Fibres and Gratings. The project aims to provide the next generation of laser and sensor technologies, benefiting not only advanced instrument industries but also others involved with materials processing, sensing diagnostics, biomedicine and defence. The search for a universal model of light interactions with all photosensitive materials, coupled with a demonstration of nanotechnology within a fi ....Advanced Laser, Sensor and Diagnostic Technologies Using New Generation Micro- and Nano- Structured Fibres and Gratings. The project aims to provide the next generation of laser and sensor technologies, benefiting not only advanced instrument industries but also others involved with materials processing, sensing diagnostics, biomedicine and defence. The search for a universal model of light interactions with all photosensitive materials, coupled with a demonstration of nanotechnology within a fibre, will lead to new gratings and fibres that underpin these technologies as well as open up new techniques and processes such as practical radiation hardening of optical waveguides.Read moreRead less
Laboratory in a Fibre: diagnostic, sensing and telecommunications technologies. The lab-in-a-fibre aims to provide the next generation of diagnostic, sensing and telecommunications technologies. Mass production of km long optical fibre platforms for the lab-in-a-fibre offers cost competitive alternative to lab-on-a-chip technologies in applications where several diagnostic, sensing processes or component technologies are required. It will benefit not only advanced instrument industries but also ....Laboratory in a Fibre: diagnostic, sensing and telecommunications technologies. The lab-in-a-fibre aims to provide the next generation of diagnostic, sensing and telecommunications technologies. Mass production of km long optical fibre platforms for the lab-in-a-fibre offers cost competitive alternative to lab-on-a-chip technologies in applications where several diagnostic, sensing processes or component technologies are required. It will benefit not only advanced instrument industries but also others involved with materials processing, sensing diagnostics, biomedicine and defence. The overall integration within the program will provide the mechanism to create new, highly skilled Australian industries.Read moreRead less
Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be ....Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be developed that will add to the nation's skill base. The outcomes of the project will enhance Australia's knowledge capacity, research capability and will contribute significantly to each of the National Research Priorities.Read moreRead less
Complex Dopant Diffusivity in Photonic Crystal Fibres and Applications. The outcomes of this research in the area of doped photonic crystal fibres will enable Australia to commercialise the technology and provide an opportunity for leading commercial ventures using novel doped PCF. These opportunities will eventually become large-scale industrial activities developed from the research in fields such as sensing, biophotonics, medical and defence and will result in significant economic benefit for ....Complex Dopant Diffusivity in Photonic Crystal Fibres and Applications. The outcomes of this research in the area of doped photonic crystal fibres will enable Australia to commercialise the technology and provide an opportunity for leading commercial ventures using novel doped PCF. These opportunities will eventually become large-scale industrial activities developed from the research in fields such as sensing, biophotonics, medical and defence and will result in significant economic benefit for Australia. Fundamental research outcomes in glass and dopants that can boost devices and introduce novel devices resulting from this project will contribute to all National Research Priorities.Read moreRead less
Optical coherence elastography - High-resolution medical imaging of tissue mechanical properties. This project brings together an international, multi-disciplinary team to develop innovative, high-resolution techniques to identify diseased tissue. Success will result in a new medical imaging technique allowing clinicians to quantify the mechanical properties of tissue, effectively creating a high-resolution image of what the tissue 'feels' like. This may help them to more accurately identify can ....Optical coherence elastography - High-resolution medical imaging of tissue mechanical properties. This project brings together an international, multi-disciplinary team to develop innovative, high-resolution techniques to identify diseased tissue. Success will result in a new medical imaging technique allowing clinicians to quantify the mechanical properties of tissue, effectively creating a high-resolution image of what the tissue 'feels' like. This may help them to more accurately identify cancerous tissue during surgery and reduce rates of recurrence. It could aid in tissue engineering and regeneration and will provide a new database of tissue mechanical properties. The project will position Australia as a leader in this newly developing medical imaging technology, with significant potential for commercialisation.Read moreRead less