Radiation protection for space, aviation, and terrestrial applications: the development of novel radiation detectors and computational techniques. Personnel in space, aviation, and terrestrial applications may be exposed to potentially harmful levels of densely ionising radiation. This project will produce improved radiation detectors and computational techniques, addressing needs in the prediction and assessment of equivalent dose in these applications. The "preventative healthcare" priority go ....Radiation protection for space, aviation, and terrestrial applications: the development of novel radiation detectors and computational techniques. Personnel in space, aviation, and terrestrial applications may be exposed to potentially harmful levels of densely ionising radiation. This project will produce improved radiation detectors and computational techniques, addressing needs in the prediction and assessment of equivalent dose in these applications. The "preventative healthcare" priority goal of the National Research Priority "Promoting and Maintaining Good Health" will be addressed, serving to reduce the risk to personnel involved in such activities. This research will also enhance Australia's international reputation in this field, stimulate local expertise, and create a critical mass of researchers in this field. Read moreRead less
Development of innovative radiation detectors and computational techniques for improving quality of life. This project will produce improved radiation detectors and advanced computational techniques, addressing needs in the prediction and assessment of the effects of radiation in homeland security, medicine, aviation and space applications. The 'preventative healthcare' priority goal of the National Research priority 'Promoting and maintaining good health' will be addressed, serving to reduce th ....Development of innovative radiation detectors and computational techniques for improving quality of life. This project will produce improved radiation detectors and advanced computational techniques, addressing needs in the prediction and assessment of the effects of radiation in homeland security, medicine, aviation and space applications. The 'preventative healthcare' priority goal of the National Research priority 'Promoting and maintaining good health' will be addressed, serving to reduce the risk to people involved in such activities. This fundamental research will also enhance Australia's international reputation in this field, stimulate local expertise and create a critical mass of researchers working in this sector.Read moreRead less
Advanced Atomic Sources for Precision Measurement. Many advances in our technology-driven society rely on the precision measurement of quantities such as accelerations, magnetic and electric fields. A higher level of measurement precision leads to a clear economic or strategic advantage. We expect to provide the Australian industrial and government sectors with new and better methods for making precise measurements with accelerometers, gyroscopes and gravity gradiometers. This proposal will pla ....Advanced Atomic Sources for Precision Measurement. Many advances in our technology-driven society rely on the precision measurement of quantities such as accelerations, magnetic and electric fields. A higher level of measurement precision leads to a clear economic or strategic advantage. We expect to provide the Australian industrial and government sectors with new and better methods for making precise measurements with accelerometers, gyroscopes and gravity gradiometers. This proposal will place Australia with only a handful of other countries as an international leader in the new technology of coherent atom interferometry. It is expected that this proposal will lead to innovative prototype devices as well as significant patentable technology. Read moreRead less
Diamond-based Ultra Violet (UV)-emitting devices. The development of UV-emitting solid state devices will enable new applications and drive rapid growth of new industries in particular in health care (sterilisation), microelectronics (lithography) and high-density data storage. With its deep expertise in photonics, Australia is well positioned to become a significant player in these industries. This collaborative project, involving academic and industrial partners, seeks to leverage Australian s ....Diamond-based Ultra Violet (UV)-emitting devices. The development of UV-emitting solid state devices will enable new applications and drive rapid growth of new industries in particular in health care (sterilisation), microelectronics (lithography) and high-density data storage. With its deep expertise in photonics, Australia is well positioned to become a significant player in these industries. This collaborative project, involving academic and industrial partners, seeks to leverage Australian scientific expertise to create new hybrid diamond/nitride structures potentially capable of emitting UV-radiation with high-efficiency and power. The outcomes will help seed new industry and economic growth in Australia.Read moreRead less
High-average-power all-solid-state lasers based on new crystalline Raman materials. We have recently made significant advances in development of all-solid-state intracavity Raman lasers generating multiwatt average powers in the near infrared and (by frequency doubling) visible spectrum, with important applications in biomedicine and remote sensing. A new generation of Raman crystals, especially tungstates, offer superior optical, mechanical and thermal properties, promising high Raman gains and ....High-average-power all-solid-state lasers based on new crystalline Raman materials. We have recently made significant advances in development of all-solid-state intracavity Raman lasers generating multiwatt average powers in the near infrared and (by frequency doubling) visible spectrum, with important applications in biomedicine and remote sensing. A new generation of Raman crystals, especially tungstates, offer superior optical, mechanical and thermal properties, promising high Raman gains and choice of Stokes frequency shift. The project will investigate a range of key issues for these materials including control of the Stokes wavelength, associated polarisation control, and pump-resonator configurations giving maximum Raman laser power and efficiency. The project will lead to state-of-the-art source technology with outstanding prospects for commercialisation and practical application.Read moreRead less
Optically-driven micromachines and microtools. The use of optical forces to trap and manipulate microscopic particles has developed from a novelty into a widely used versatile research tool - optical tweezers. New advances, such as the application and optical measurement of optical torque, have been brought to the brink of practical application. We will apply these methods to the development and production of micromachines of unprecedently small size, and the development of new medical diagnosti ....Optically-driven micromachines and microtools. The use of optical forces to trap and manipulate microscopic particles has developed from a novelty into a widely used versatile research tool - optical tweezers. New advances, such as the application and optical measurement of optical torque, have been brought to the brink of practical application. We will apply these methods to the development and production of micromachines of unprecedently small size, and the development of new medical diagnostic techniques, and industrial and research tools.Read moreRead less
Quantitative polarisation phase microscopy: A new tool for advances in structural analysis and biophotonics. Innovation in biomedical research is driven by technology in optical imaging. Optical imaging methods including polarisation microscopy are widely accepted and are at the forefront of biomedical scientific discoveries. This project undertakes fundamental and applied research innovatively combining polarisation imaging and quantitative phase imaging microscopy to uniquely quantify the phys ....Quantitative polarisation phase microscopy: A new tool for advances in structural analysis and biophotonics. Innovation in biomedical research is driven by technology in optical imaging. Optical imaging methods including polarisation microscopy are widely accepted and are at the forefront of biomedical scientific discoveries. This project undertakes fundamental and applied research innovatively combining polarisation imaging and quantitative phase imaging microscopy to uniquely quantify the physical thickness and morphology of birefringent specimens such as the cardiac muscle cell. This project, while of substantial intellectual merit in its own right, could also have the potential to lead to the detection of the mechanisms related to heart failure. Read moreRead less
New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray s ....New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray scientists of tomorrow, whose expertise will allow Australia to capitalize on its investment in the Australian Synchrotron.Read moreRead less
Fibre Optic Dosimeters for Medical and Environmental Applications. We will develop fibre optic dosimeters for environmental monitoring and radiation therapy. A novel approach using refractive index gradients will be used to capture scintillator light while rejecting noise. New knowledge will be gained of the mechanisms of radiation damage in scintillators and glasses. The small, flexible, accurate fibre optic dosimeters will be equivalent in absorbing characteristics to human tissue, making them ....Fibre Optic Dosimeters for Medical and Environmental Applications. We will develop fibre optic dosimeters for environmental monitoring and radiation therapy. A novel approach using refractive index gradients will be used to capture scintillator light while rejecting noise. New knowledge will be gained of the mechanisms of radiation damage in scintillators and glasses. The small, flexible, accurate fibre optic dosimeters will be equivalent in absorbing characteristics to human tissue, making them superior to all currently available dosimeters. Fibre optic dosimeters will enable new adaptive radiotherapy techniques and provide quality assurance of dose delivery in radiotherapy. Their multiplexing capability will lead to applications in monitoring of workplaces and aerospace environments.Read moreRead less
Scaling-up microstructured fibres for terahertz radiation. Terahertz radiation is the last region of the electromagnetic spectrum to be fully utilised. Many applications have been identified but their practicality has been limited by a lack of low-loss flexible waveguides. The waveguides to be developed in this project will build on Australia's existing international lead and investments in photonics as well as extend the dynamic field of microstructured optical fibres, indentified as the 'futur ....Scaling-up microstructured fibres for terahertz radiation. Terahertz radiation is the last region of the electromagnetic spectrum to be fully utilised. Many applications have been identified but their practicality has been limited by a lack of low-loss flexible waveguides. The waveguides to be developed in this project will build on Australia's existing international lead and investments in photonics as well as extend the dynamic field of microstructured optical fibres, indentified as the 'future' of optical fibres. Low-loss flexible waveguides will enable imaging and spectroscopy applications that can reveal and object's internal structure and composition. This will have immediate applications in security, quality control, medical imaging and other safety or industrial applications.Read moreRead less