Condition Assessment of Medium-Voltage XLPE-Insulated Cables Degraded by Water Treeing. In Australia degraded underground XLPE cables are causing disruption of electricity supplies and high community costs. There is no reliable non-invasive technique for prediction of cable condition to optimise cable replacement and refurbishment. In this project a large-scale experiment will be undertaken on 22 kV cables to ascertain the effectiveness of a new cable refurbishment technology. New techniques for ....Condition Assessment of Medium-Voltage XLPE-Insulated Cables Degraded by Water Treeing. In Australia degraded underground XLPE cables are causing disruption of electricity supplies and high community costs. There is no reliable non-invasive technique for prediction of cable condition to optimise cable replacement and refurbishment. In this project a large-scale experiment will be undertaken on 22 kV cables to ascertain the effectiveness of a new cable refurbishment technology. New techniques for assessment of cable condition will be developed using unique data from the ageing experiment and computer models of fundamental phenomena. Successful conclusions from this project will save the industry partner and other electricity distribution companies tens of millions of dollars.Read moreRead less
Tunable nonlinear photonic devices with liquid crystals. This project will help to initiate in Australia a systematic study of nonlinear properties of liquid crystals for applications in optical components. Taking the advantage of strong and tunable nonlinear response of liquid crystals and low threshold powers, it will analyse new opportunities for controllable light manipulation in nanoscale photonic devices, suggesting realistic designs for tunable photonic circuits. The project will promote ....Tunable nonlinear photonic devices with liquid crystals. This project will help to initiate in Australia a systematic study of nonlinear properties of liquid crystals for applications in optical components. Taking the advantage of strong and tunable nonlinear response of liquid crystals and low threshold powers, it will analyse new opportunities for controllable light manipulation in nanoscale photonic devices, suggesting realistic designs for tunable photonic circuits. The project will promote this attractive field and will facilitate the emergence of novel technologies. It will also lead to important international collaborations and bring important new expertise to Australia, complementing the core research program of the ARC Centre of Excellence CUDOS.Read moreRead less
Microwave Antennas and Waveguides in Photonic Crystals. We propose to design a revolutionary new class of microwave antennas and antenna arrays in photonic crystals, which can shield, localise and guide electromagnetic radiation in a dielectric environment. This design is completely devoid of metal, thereby eliminating skin-effect losses that are the dominant limitation for planar antenna arrays at upper microwave (millimetre-wave) frequencies. Our new design will achieve high radiation efficie ....Microwave Antennas and Waveguides in Photonic Crystals. We propose to design a revolutionary new class of microwave antennas and antenna arrays in photonic crystals, which can shield, localise and guide electromagnetic radiation in a dielectric environment. This design is completely devoid of metal, thereby eliminating skin-effect losses that are the dominant limitation for planar antenna arrays at upper microwave (millimetre-wave) frequencies. Our new design will achieve high radiation efficiencies and antenna gains not possible with existing planar technology, thereby enabling new applications of planar antenna arrays, for example to radio astronomy, as well as greatly improving existing applications.Read moreRead less
Composite magnetic conducting nanomaterials for microwave applications. Australian science and technology will be a leading participant in the creation of a new, useful technology for microwave and magnetologic applications whose properties arise from integration of metallic magnetic nanoelements with miniature nonmagnetic current conductors. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale. In this project, young Australian scientists and research ....Composite magnetic conducting nanomaterials for microwave applications. Australian science and technology will be a leading participant in the creation of a new, useful technology for microwave and magnetologic applications whose properties arise from integration of metallic magnetic nanoelements with miniature nonmagnetic current conductors. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale. In this project, young Australian scientists and research students will have opportunities to receive training and become involved in a National Priority Frontier Technology rich in possibilities for generation of intellectual property.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453911
Funder
Australian Research Council
Funding Amount
$391,529.00
Summary
Microwave Antenna Testing Facility for Far-Field and Spherical Near-Field Measurements. The proposed facility is for testing broad-beam microwave antennas (1 GHz - 18 GHz), designed and developed by collaborators for several research and commercial projects. These antennas are important in telecommunications, defence and biomedical applications. While facilitating timely pattern measurements of antenna prototypes, it will open new opportunities in antenna experimentation. This facility will enha ....Microwave Antenna Testing Facility for Far-Field and Spherical Near-Field Measurements. The proposed facility is for testing broad-beam microwave antennas (1 GHz - 18 GHz), designed and developed by collaborators for several research and commercial projects. These antennas are important in telecommunications, defence and biomedical applications. While facilitating timely pattern measurements of antenna prototypes, it will open new opportunities in antenna experimentation. This facility will enhance collaborators' highly acclaimed theoretical research by providing experimental results for theory validation. Near-field patterns available from the facility will advance our knowledge on complicated antennas. This will generate researchers skilled in state-of-the art antenna measurements, and will help develop competitive Australian industries in this frontier technology.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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Left-handed metamaterials and negative refraction. This project will establish and support the first team in Australia working in the field of left-handed metamaterials, artificial materials in which waves behave in a unique and counter-intuitive way. The project will promote this new field, enhance its rapid development, and facilitate emerging novel technologies in Australia. It will also lead to close international collaborations with active theoretical and experimental groups, and bring impo ....Left-handed metamaterials and negative refraction. This project will establish and support the first team in Australia working in the field of left-handed metamaterials, artificial materials in which waves behave in a unique and counter-intuitive way. The project will promote this new field, enhance its rapid development, and facilitate emerging novel technologies in Australia. It will also lead to close international collaborations with active theoretical and experimental groups, and bring important expertise to Australia. We believe our initial efforts of purely fundamental nature and extensive collaboration with the overseas groups will have a significant impact on the development of this field and related novel technologies in Australia, attracting strong interest from industry.Read moreRead less
Engineering and control of metamaterials with negative refraction. This project will extend significantly the research activity on metamaterials in Australia, promoting this new field and aiming to solve high priority problems and paving the way to creation of practical sub-wavelength devices. This project is therefore of national benefit for its advances in critical fundamental research and for potential applications in a large number of engineering tasks in microwave and optical devices. The p ....Engineering and control of metamaterials with negative refraction. This project will extend significantly the research activity on metamaterials in Australia, promoting this new field and aiming to solve high priority problems and paving the way to creation of practical sub-wavelength devices. This project is therefore of national benefit for its advances in critical fundamental research and for potential applications in a large number of engineering tasks in microwave and optical devices. The project will initialize collaboration with world leading experts in the area, bringing important expertise to Australia. It will provide a greater acceptance of Australia as a major world player in fundamental research.Read moreRead less
Photonic Crystal Signal Processing and Antenna Technologies. The information society in which we live requires increasingly high bandwidth, low cost communications. This project addresses two critically important technologies needed to meet these demands: signal processing devices and antennas. These devices will be designed using three-dimensional photonic crystals, which provide excellent possibilities for low-cost, highly integrated photonic circuits. Working prototypes will be built at micro ....Photonic Crystal Signal Processing and Antenna Technologies. The information society in which we live requires increasingly high bandwidth, low cost communications. This project addresses two critically important technologies needed to meet these demands: signal processing devices and antennas. These devices will be designed using three-dimensional photonic crystals, which provide excellent possibilities for low-cost, highly integrated photonic circuits. Working prototypes will be built at microwave frequencies, but due to the scalability of electromagnetic theory these results are also valid in the optical domain. The outcomes of this project will be accurate theoretical models and empirical tests for new technologies that satisfy the future needs of the information society.Read moreRead less
Polar Cap Region Boundary Dynamics. Geomagnetic storms have the potential to severely impair critical technology infrastructure. Consequences of strong geomagnetic activity can include power failures, pipeline corrosion, satellite failures, inaccurate GPS positioning and radio navigation. Knowledge of how, where and under which conditions this activity occurs is therefore crucial. The primary aim of this project is to extend our knowledge of the mechanisms by which this activity occurs. This wor ....Polar Cap Region Boundary Dynamics. Geomagnetic storms have the potential to severely impair critical technology infrastructure. Consequences of strong geomagnetic activity can include power failures, pipeline corrosion, satellite failures, inaccurate GPS positioning and radio navigation. Knowledge of how, where and under which conditions this activity occurs is therefore crucial. The primary aim of this project is to extend our knowledge of the mechanisms by which this activity occurs. This work will consolidate Australia's international space profile and provide excellent training in this field, helping Australia's future technology development.Read moreRead less