Levitated Quantum Optomechanics with Trapped, Rotating Microparticles. This project will develop techniques for trapping, rotating and cooling microscopic particles in vacuum for exquisitely accurate studies of sensors and of fundamental physics at the classical-quantum interface - namely quantum vacuum friction. It will result in the establishment of an internationally recognised activity in rotational levitated optomechanics and expand Australia's presence in the field of quantum photonics. It ....Levitated Quantum Optomechanics with Trapped, Rotating Microparticles. This project will develop techniques for trapping, rotating and cooling microscopic particles in vacuum for exquisitely accurate studies of sensors and of fundamental physics at the classical-quantum interface - namely quantum vacuum friction. It will result in the establishment of an internationally recognised activity in rotational levitated optomechanics and expand Australia's presence in the field of quantum photonics. It has the potential for commercial benefit in areas including photonics, sensors and advanced manufacturingRead moreRead less
Australian Laureate Fellowships - Grant ID: FL210100099
Funder
Australian Research Council
Funding Amount
$3,401,828.00
Summary
The Intelligent Microscope - novel optical imaging at depth. While optical methods for imaging are used extensively, achieving wide-field imaging through scattering media with high resolution and depth is a major challenge, due mainly to the limited penetration depth of light. This proposal aims to transform wide-field optical imaging through a new ‘intelligent’ microscopy able to capture 3D volumetric images. Innovations in shaping light in both space and time will be combined in a holistic wa ....The Intelligent Microscope - novel optical imaging at depth. While optical methods for imaging are used extensively, achieving wide-field imaging through scattering media with high resolution and depth is a major challenge, due mainly to the limited penetration depth of light. This proposal aims to transform wide-field optical imaging through a new ‘intelligent’ microscopy able to capture 3D volumetric images. Innovations in shaping light in both space and time will be combined in a holistic way with computational analysis to extract images from deep within the sample at extraordinary levels of detail. Major benefits of the research range from next-generation tools for enhanced discovery of biological and physical materials, to new Australian start-ups for new imaging and microscopy devices.Read moreRead less
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.
Laser emission at the limit of glass transparency using nanocrystal doping . We will create a new composite glass providing strong fluorescence which fully exploits the high transmission of glass in the mid-infrared. When combined with emerging rare earth ion transitions and precise excitation processes, this project will help solve an important problem in optics; that the overall efficiency and power produced from deep mid-infrared light sources is not sufficient for all industries. The primary ....Laser emission at the limit of glass transparency using nanocrystal doping . We will create a new composite glass providing strong fluorescence which fully exploits the high transmission of glass in the mid-infrared. When combined with emerging rare earth ion transitions and precise excitation processes, this project will help solve an important problem in optics; that the overall efficiency and power produced from deep mid-infrared light sources is not sufficient for all industries. The primary outcome will be a series of robust fibre-based gain modules suitable for high power and very short optical pulses in the mid-infrared. These light sources will beneficially impact medicine, defence, sensing and manufacturing providing excellent opportunities for increasing Australian productivity and global competitiveness. Read moreRead less
Ultra-high spectral purity lasers for tests of relativity and atomic clocks. Measurement precision is the key to advancement of a technological society. This project aims to build the most precise measurement tool ever developed: one capable of delivering 17 digits of precision in just 1 second. In conjunction with German and French colleagues this too will be used to test the foundation theories of physics.
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100121
Funder
Australian Research Council
Funding Amount
$720,000.00
Summary
Equipment for International Collaboration in Gravitational Wave Detection. Equipment for international collaboration in gravitational wave detection: This project will allow the Australian Consortium for Gravitational Astronomy to install optical equipment at its dedicated research facility, and to install data analysis pipelines on new iVEC Pawsey Centre GPU-enabled supercomputers. The equipment is required for research aimed at stabilising instabilities in the new international gravitational w ....Equipment for International Collaboration in Gravitational Wave Detection. Equipment for international collaboration in gravitational wave detection: This project will allow the Australian Consortium for Gravitational Astronomy to install optical equipment at its dedicated research facility, and to install data analysis pipelines on new iVEC Pawsey Centre GPU-enabled supercomputers. The equipment is required for research aimed at stabilising instabilities in the new international gravitational wave detectors currently being commissioned in the USA and Europe. Real time data from the new detectors will be analysed using innovative new techniques. Scientists across Australia will be able to rapidly localise potential gravitational wave sources to direct robotic telescope observations. This could enable the first detection of gravitational waves.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882792
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
High Power Laser, Test Masses, Digital Control System and Vacuum System for High Optical Power Interferometry Experiments. Gravitational waves are expected to offer humanity a completely new spectrum with which to study the Universe. Australia has been a pioneer in the quest to open up this new spectrum. This project will allow Australia to play a key role in a world-wide project which aims for the first time to enable gravitational waves to be detected from black holes and neutron stars through ....High Power Laser, Test Masses, Digital Control System and Vacuum System for High Optical Power Interferometry Experiments. Gravitational waves are expected to offer humanity a completely new spectrum with which to study the Universe. Australia has been a pioneer in the quest to open up this new spectrum. This project will allow Australia to play a key role in a world-wide project which aims for the first time to enable gravitational waves to be detected from black holes and neutron stars throughout the universe. It will give Australia access to developed technologies, and will be a major boost to physical science research and education.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.