Oscillating water column efficiency improvement through impedance matching and active latching control techniques. The coastline of southern Australia is recognised as a world-class wave energy resource. This project will play a crucial role in seeing this resource exploited whilst simultaneously keeping Australia at the forefront of wave energy technology. Specifically, this project will develop a high-efficiency turbine technology for wave
energy.
High power density, low cogging torque and low-cost micro-scale wind turbine generator system utilising soft magnetic composite materials. This project will develop a low-cost, high-performance and high-ef?ciency micro-scale wind turbine generator using a new magnetic material consisting of iron powder, which can be easily pressed into any desirable shape. This allows considerably simpli?ed manufacturing, greater design ?exibility and ease of scaling to higher output powers.
Advanced eyesafe Er:YAG short pulsed lasers for remote sensing applications. This project will develop state-of-the-art tunable pulsed Er:YAG laser systems that will represent a significant advance for eyesafe remote sensing and range finder technologies. It will render obsolete, current state-of-the-art systems for laser ranging and enable remote sensing of a critical greenhouse gas.
Ultra-low-loss fluoride glass optical fibres for the future global network. The transmission loss of silica optical fibres limits the capacity of the global internet. Fluoride glass fibres have the potential of reducing the loss by more than 10 times. This project aims to overcome two of the technological challenges of the ultra-low-loss fluoride fibre optics network: (1) commercial-scale manufacturing of improved fibres and (2) signal amplification at 2.3μm. By generating new fundamental knowle ....Ultra-low-loss fluoride glass optical fibres for the future global network. The transmission loss of silica optical fibres limits the capacity of the global internet. Fluoride glass fibres have the potential of reducing the loss by more than 10 times. This project aims to overcome two of the technological challenges of the ultra-low-loss fluoride fibre optics network: (1) commercial-scale manufacturing of improved fibres and (2) signal amplification at 2.3μm. By generating new fundamental knowledge on rare-earth transitions and glass crystal formation, expected outcomes include innovative fibre fabrication methods optimised for space manufacturing. Benefits will include enhanced internet capacity with lower energy requirements, and opportunities for sovereign capability in fluoride fibre fabrication in Australia.Read moreRead less
Compact and versatile chip lasers for three-dimensional mine surveying. This project will bring together a world leading mine survey company, The University of Adelaide and Macquarie University researchers, to develop an 'eye-safe' micro laser for high resolution three-dimensional laser-mapping. The recently developed and patented 'chip' laser will allow the realisation of a compact, enhanced range laser-radar with unmatched resolution.
Laser Airborne Methane Sensor. Fugitive emissions of methane represent a significant economic loss to the natural gas industry. This project aims to develop a new laser based methane sensing platform for deployment on fixed wing aircraft. This aims to allow the spatial concentration of methane to be mapped rapidly over a broad area with unprecedented spatial resolution allowing sources to be rapidly identified and the gas captured for economic benefit. The testing of this system on an airborne p ....Laser Airborne Methane Sensor. Fugitive emissions of methane represent a significant economic loss to the natural gas industry. This project aims to develop a new laser based methane sensing platform for deployment on fixed wing aircraft. This aims to allow the spatial concentration of methane to be mapped rapidly over a broad area with unprecedented spatial resolution allowing sources to be rapidly identified and the gas captured for economic benefit. The testing of this system on an airborne platform is possible in this timeframe because of the plan to modify an existing system provided by the Partner Organisation.Read moreRead less
Creating a national time and frequency network for Australia. This project will develop the means to distribute accurate time and frequency across the Australian continent via an optical fibre network. This network will meet the needs of future telecommunications, science and astronomy projects including the Australian bid for the Square Kilometre Array radio-astronomy project.