Advanced Electromagnetic Sensors and Magnetic Gradiometers for Natural Resources Exploration and Future Space Missions. Australia will benefit from the long-standing world-class mining exploration industry. The new magnetic gradiometer system would greatly enhance their arsenal of geophysical exploration tools, especially for the detection of both magnetically and/or conductive minerals like nickel sulphide. Due to the inherent skin depth issues of conductive cover, a unique condition in Austral ....Advanced Electromagnetic Sensors and Magnetic Gradiometers for Natural Resources Exploration and Future Space Missions. Australia will benefit from the long-standing world-class mining exploration industry. The new magnetic gradiometer system would greatly enhance their arsenal of geophysical exploration tools, especially for the detection of both magnetically and/or conductive minerals like nickel sulphide. Due to the inherent skin depth issues of conductive cover, a unique condition in Australia, a low frequency electromagnetic survey system is one of the best methods to penetrate the cover and investigate deeper geological structures. The low frequency isolation system developed in this project will improve the survey instrument performance down to 4Hz, providing capability to explore resources about 50-100% deeper than existing instrumentation allows.Read moreRead less
Characterisation, development and application of novel Ion Beam technology (IBT) to enhance the optical thin film manufacturing process. Manufacture of optical thin film coatings is a difficult and generally inefficient process undertaken within a vacuum chamber. There are many variables which are not easily controlled nor understood in these complex thermodynamic environments. This project aims to advance core knowledge in three critical areas namely an improved understanding of ion beam phy ....Characterisation, development and application of novel Ion Beam technology (IBT) to enhance the optical thin film manufacturing process. Manufacture of optical thin film coatings is a difficult and generally inefficient process undertaken within a vacuum chamber. There are many variables which are not easily controlled nor understood in these complex thermodynamic environments. This project aims to advance core knowledge in three critical areas namely an improved understanding of ion beam physics, new knowledge of the thermodynamic environment used in physical vapour deposition of thin films and new knowedge in the application of Ion beam Technology to optical thin film growth and characteristics.
This project is significant, developing core knowledge and understanding with potential to lead to process efficiency gains, improved optical film characteristics and accessing new areas of research (rf/photoic devices). This project will advance the current state of art in the field of Ion Beam Technology and Ion Beam assisted physical vapour deposition.
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Application of ultra-high stability cryogenic sapphire oscillators to Very Long Baseline Interferometry. This project will develop a state-of-the-art commercial prototype of the cryogenic sapphire oscillator (CSO) optimised for use at remote sites. Proof of operation will be applied to the important niche market of Very-Long Baseline Interferometry (VLBI) radio astronomy, with improvements in image quality. The research will also significantly benefit the Australian bid for the SKA project, as ....Application of ultra-high stability cryogenic sapphire oscillators to Very Long Baseline Interferometry. This project will develop a state-of-the-art commercial prototype of the cryogenic sapphire oscillator (CSO) optimised for use at remote sites. Proof of operation will be applied to the important niche market of Very-Long Baseline Interferometry (VLBI) radio astronomy, with improvements in image quality. The research will also significantly benefit the Australian bid for the SKA project, as the CSO is the only technology capable of synchronising the outputs of the telescopes arrays to the required signal to noise to attain the required image quality. The project will further Australia's status in radio astronomy as a world leader and add to our exports of precision scientific instruments.Read moreRead less
Application of Femtosecond Light Sources to Generation of Low Noise Microwave Signals. The main goal of the research project is to develop prototypes of photonic oscillators capable of generating spectrally pure signals both at optical and microwave frequencies. The project is also aimed at understanding noise mechanisms affecting frequency stability of classical microwave oscillators based on sapphire loaded cavity resonators. By cryogenically cooling such resonators we plan to create a new fam ....Application of Femtosecond Light Sources to Generation of Low Noise Microwave Signals. The main goal of the research project is to develop prototypes of photonic oscillators capable of generating spectrally pure signals both at optical and microwave frequencies. The project is also aimed at understanding noise mechanisms affecting frequency stability of classical microwave oscillators based on sapphire loaded cavity resonators. By cryogenically cooling such resonators we plan to create a new family of extremely low noise and economically viable microwave signal sources. The research proposed will enrich the field of oscillator frequency control, give rise to new techniques for precision noise measurements and reinforce Australia's position at the forefront of microwave and photonic science.Read moreRead less
Moving-beam phase retrieval - a route to better microscopy! This research will benefit the nation by improving the quality of x-ray diffraction and electron microscopy techniques available to Australian scientists. It will make it possible to examine microscopic structures in more detail and therefore gain more information about the atomic positions in these structures. This will greatly benefit research that depends on finding the structure of very small objects. Such research areas include ....Moving-beam phase retrieval - a route to better microscopy! This research will benefit the nation by improving the quality of x-ray diffraction and electron microscopy techniques available to Australian scientists. It will make it possible to examine microscopic structures in more detail and therefore gain more information about the atomic positions in these structures. This will greatly benefit research that depends on finding the structure of very small objects. Such research areas include nanomaterials, biological engineering, medical science and materials science. The work is also expected to have industrial applications and to make an important contribution to the development of the synchrotron science industry in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347462
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectro ....Femtosecond laser micromachining facility. The proposed establishment of a femtosecond laser micromachining facility, with microdiagnostic capabilities, will facilitate a range of projects involving fabrication of submicron structures in metals, polymers, glasses, ceramics and crystalline materials. This facility, unique in Australia , will be comparable to the best such facilities in the world, enabling researchers to apply new microfabrication techniques to a range of photonic and optoelectronic devices, including laser-written optical planar waveguides, nonlinear components and photonic bandgap structures , and various biomedical microstructures. Outcomes will include demonstration and development of novel photonic/optoelectronic devices and of new techniques, crucial to cost-effective manufacture of photonic components.Read moreRead less
Optical supercontinuum generation from high pulse-energy optical sources. The aim of this project is to develop a broadband and high brightness optical fibre source based on optical supercontinuum generation (i.e. low-coherence optical signals with octave or more bandwidth). Unlike similar sources demonstrated recently which rely on expensive bulk femtosecond pump lasers, this source will be pumped by a large pulse-energy optical fibre laser and use stimulated Raman scattering to seed the contin ....Optical supercontinuum generation from high pulse-energy optical sources. The aim of this project is to develop a broadband and high brightness optical fibre source based on optical supercontinuum generation (i.e. low-coherence optical signals with octave or more bandwidth). Unlike similar sources demonstrated recently which rely on expensive bulk femtosecond pump lasers, this source will be pumped by a large pulse-energy optical fibre laser and use stimulated Raman scattering to seed the continuum generation. The primary outcome will be a compact low-cost all-fibre supercontinuum source with a wide range of applications in areas such as optical metrology, optical coherence tomography, and high resolution non-contact position and motion sensing.Read moreRead less
Ringed photonic crystal fibres for broadband nonlinear optics. The technology developed from this project will enable organic molecules to be detected, identified and quantified. Because the technology is compact, easily engineered and low cost, it will lead to a dramatically increased capability for infrared spectroscopic measurement throughout biology and medicine, with specific benefits in agriculture, the food industry and defence.
Special Research Initiatives - Grant ID: SR0354630
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
Fluorescence Applications in Biotechnology and Life Sciences. The Network in Fluorescence applications in biotechnology and life sciences will coordinate a research program relating to applications of fluorescence whose proper resolution requires a high degree of interaction between biology, physics, chemistry, bioengineering and medicine. These would be applied to industrially relevant problems in areas such as public health, biotechnology, safety of foods, chemical biology and environmental mo ....Fluorescence Applications in Biotechnology and Life Sciences. The Network in Fluorescence applications in biotechnology and life sciences will coordinate a research program relating to applications of fluorescence whose proper resolution requires a high degree of interaction between biology, physics, chemistry, bioengineering and medicine. These would be applied to industrially relevant problems in areas such as public health, biotechnology, safety of foods, chemical biology and environmental monitoring. Approaches such as highly selective fluorescent labelling of targets using appropriate immunological and molecular techniques and purpose-engineered fluorochromes accompanied by the development of specialised instrumentation will capitalise on the multi-disciplinary research strengths in Australia and lead towards tangible industrial outcomes.
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ARC/NHMRC Research Network Fluorescence Applications in Biotechnology and Life Sciences. This Network will concentrate Australian research in new applications of fluorescence to biological systems to solve significant problems in health diagnostics, biotechnology and the environment. The scientific goals identified by the Network such as highly selective fluorescent labelling and purpose-engineered fluorochromes will be accompanied by the development of specialised instrumentation. These resear ....ARC/NHMRC Research Network Fluorescence Applications in Biotechnology and Life Sciences. This Network will concentrate Australian research in new applications of fluorescence to biological systems to solve significant problems in health diagnostics, biotechnology and the environment. The scientific goals identified by the Network such as highly selective fluorescent labelling and purpose-engineered fluorochromes will be accompanied by the development of specialised instrumentation. These research directions pursued by strong multi-disciplinary teams spanning biology, chemistry, physics, bioengineering and medicine will benefit from the support of the Network programs. Through its focus on academic - industry collaboration the Network will also facilitate development of basic scientific discoveries into commercial outcomes.Read moreRead less