Australian Centre for Quantum-Atom Optics. The Centre will combine pre-eminent Australian theoretical and experimental research groups in quantum and atom optics to create a powerful network to advance the rapidly developing field of Quantum-Atom Optics. We will exploit the quantum nature of multiple particle quantum states of atoms and photons including entangled light and Bose-Einstein condensates. The Centre will focus on fundamental research, but our long term goal is to underpin and develo ....Australian Centre for Quantum-Atom Optics. The Centre will combine pre-eminent Australian theoretical and experimental research groups in quantum and atom optics to create a powerful network to advance the rapidly developing field of Quantum-Atom Optics. We will exploit the quantum nature of multiple particle quantum states of atoms and photons including entangled light and Bose-Einstein condensates. The Centre will focus on fundamental research, but our long term goal is to underpin and develop the next generation quantum technology. We aim to build a quantum toolbox to enable applications such as the transfer and storage of information for photonics, and precision quantum control of atoms for enhanced atom interferometry.Read moreRead less
Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity ....Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity. Australia's high tech industry will benefit from the commercialisation opportunities arising from the Centre's research, and also from the creation of a pool of highly skilled ICT professionals.Read moreRead less
Study of the ionospheric E region during disturbed geomagnetic conditions using stereoscopic HF radar observations. This project is expected to benefit Australia by: maintaining and expanding Australia's traditionally strong research positions in the field of space physics; conducting leading edge research in the rapidly expanding field of geomagnetic storm effects on technological systems; establishing bi-directional transfer of radar technology between Australia and international partners; pro ....Study of the ionospheric E region during disturbed geomagnetic conditions using stereoscopic HF radar observations. This project is expected to benefit Australia by: maintaining and expanding Australia's traditionally strong research positions in the field of space physics; conducting leading edge research in the rapidly expanding field of geomagnetic storm effects on technological systems; establishing bi-directional transfer of radar technology between Australia and international partners; providing unique training in space science and advanced data processing highly valued by industry, government and academia' potentially leading to significant improvements in performance and stability of satellite communication and positioning systems; and supporting Australia's critical infrastructure such as surveillance and power distribution networks.Read moreRead less
Plasma layers, waves and fountains: Probing the ionosphere with over-the-horizon radars. The ionised layers of the Earth’s upper atmosphere – the ionosphere - bend radio waves emitted by HF radio communication and radar surveillance systems allowing detection of targets beyond the horizon. This research will provide direct scientific support to this infrastructure including the $1.8B Australian coastal surveillance radars used to locate and track ships and planes in our region and radio communic ....Plasma layers, waves and fountains: Probing the ionosphere with over-the-horizon radars. The ionised layers of the Earth’s upper atmosphere – the ionosphere - bend radio waves emitted by HF radio communication and radar surveillance systems allowing detection of targets beyond the horizon. This research will provide direct scientific support to this infrastructure including the $1.8B Australian coastal surveillance radars used to locate and track ships and planes in our region and radio communication links used by military personnel and civilians living or travelling in Australia’s remote territories. This project will also provide training in areas highly relevant to our partners in government and defense, potentially improve efficiency of scientific and military radars, and thus contribute to improving national security.Read moreRead less
Innovation in photonic device imaging: The keystone for future technologies. Advances in the use of photonic technology in telecommunications and a range of industrial applications depend critically on a precise knowledge of the physical structure of the optical fibre or device. This project involves the development of a suite of precision imaging techniques for determining the structure of optical fibres and in-fibre devices such as gratings and its application to a range of important problems ....Innovation in photonic device imaging: The keystone for future technologies. Advances in the use of photonic technology in telecommunications and a range of industrial applications depend critically on a precise knowledge of the physical structure of the optical fibre or device. This project involves the development of a suite of precision imaging techniques for determining the structure of optical fibres and in-fibre devices such as gratings and its application to a range of important problems in optical fibre technology. This knowledge is central to the ability to optimise and improve fibre and device fabrication methods, laying the foundations for higher speed telecommunications and the production of novel photonic devices.Read moreRead less
Centre for Mathematical and Statistical Modelling of Complex Systems. This Centre, formed by a group of high-profile researchers, brings expertise from linked but hitherto disparate areas together. It will place Australia at the forefront of research into complex systems.
The mission of the Centre is to stimulate research in mathematical and statistical modelling of complex systems and to encourage cross-fertilisation of ideas and techniques. The specific objectives are
- to formulate and ana ....Centre for Mathematical and Statistical Modelling of Complex Systems. This Centre, formed by a group of high-profile researchers, brings expertise from linked but hitherto disparate areas together. It will place Australia at the forefront of research into complex systems.
The mission of the Centre is to stimulate research in mathematical and statistical modelling of complex systems and to encourage cross-fertilisation of ideas and techniques. The specific objectives are
- to formulate and analyse mathematical and statistical models for natural and artificial complex systems,
- to use these models to develop an understanding of the behaviour of these systems
- to incorporate this understanding into strategies for management and control.Read moreRead less
Expanding the boundaries of long distance, high capacity data transmission in optical fibres. The aims of the project are to investigate the interrelationships between various transmission impairments and to develop corresponding management strategies for 40 Gbit/s based wavelength division multiplexed optical transmission systems, to expand the boundaries of current fibre optic links and networks. The project will help underpin the future development of the telecommunications sector of the Aust ....Expanding the boundaries of long distance, high capacity data transmission in optical fibres. The aims of the project are to investigate the interrelationships between various transmission impairments and to develop corresponding management strategies for 40 Gbit/s based wavelength division multiplexed optical transmission systems, to expand the boundaries of current fibre optic links and networks. The project will help underpin the future development of the telecommunications sector of the Australian photonics industry, and enhance Australia's long-term capabilities in long haul optical transmission. The expected outcomes of this project are to strengthen Australia's international photonics profile, create new commercialisation opportunities, and provide critical capabilities for future Australian commercial ventures in this area.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0221428
Funder
Australian Research Council
Funding Amount
$530,000.00
Summary
A Transportable Optical Frequency Counter, Synthesizer and Super-Continuum Generator (OFCSSG). The generation of ultra-short light pulses of just a few femtoseconds (one thousand-trillionth of a second) in duration has enabled applications in a wide range of fields, but complexity and cost has limited availability. This project will employ recently developed optical fibre and solid-state laser technology to create a cost-effective compact transportable facility of highly coherent, ultra-broadba ....A Transportable Optical Frequency Counter, Synthesizer and Super-Continuum Generator (OFCSSG). The generation of ultra-short light pulses of just a few femtoseconds (one thousand-trillionth of a second) in duration has enabled applications in a wide range of fields, but complexity and cost has limited availability. This project will employ recently developed optical fibre and solid-state laser technology to create a cost-effective compact transportable facility of highly coherent, ultra-broadband radiation. The source will enable new research and substantially enrich existing research in optical time standards and metrology, in-vivo biological imaging, and ultrafast spectroscopy. No such facility is presently available in AustraliaRead moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775614
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
National Electromagnetic Characterization Facility for Advanced Electronic and Biomaterials. The proposed Material Characterisation Facility using non-destructive methods will be unique to Australia. Precise characterisation of advanced materials such as dielectrics and superconductors using the facility will progress emerging technologies within the electronic and communication research area. The inclusion of a microwave scanning test bed within the laboratory will allow engineers, scientists, ....National Electromagnetic Characterization Facility for Advanced Electronic and Biomaterials. The proposed Material Characterisation Facility using non-destructive methods will be unique to Australia. Precise characterisation of advanced materials such as dielectrics and superconductors using the facility will progress emerging technologies within the electronic and communication research area. The inclusion of a microwave scanning test bed within the laboratory will allow engineers, scientists, biologists and medical scientists to safely detect the intrinsic electromagnetic properties of electronic materials and tumours in biological tissues or poor quality agricultural produce. This comprehensive material characterisation facility will therefore benefit the peoples of Australasia in many significant and diverse ways.Read moreRead less