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
Improving optical data storage and micromachining technology through better modelling and characterisation of their laser beams. The laser sources generally do not have simple (Gaussian) distributions. The applicant has recently developed a model, describing free propagation of complex (non-Gaussian) laser beams. This project seeks to develop a comprehending model for laser beams propagation through complex optical systems. The effects of various optical elements will be defined employing a no ....Improving optical data storage and micromachining technology through better modelling and characterisation of their laser beams. The laser sources generally do not have simple (Gaussian) distributions. The applicant has recently developed a model, describing free propagation of complex (non-Gaussian) laser beams. This project seeks to develop a comprehending model for laser beams propagation through complex optical systems. The effects of various optical elements will be defined employing a novel method known as SAFE (Stable Aggregate of Flexible Elements) which is a compromise between geometrical and physical optics. Applying this model to micromachining and optical data storage (ODS), which need high beam quality (low divergence and good focussibility), enable accurate predictive capability critical to the optimisation of micromachining and ODS designs.Read moreRead less
Ultrafast photonic hammer: A new strategy to synthesise super-dense super-hard nanomaterials. We will develop a new way for laboratory synthesis of new classes of super-hard and super-dense materials at and above the extremely high temperature and density range currently accessible only in nuclear explosions. The ability of ultra-fast laser-induced phase transformations will be exploited aiming to form materials with exotic properties, which are theoretically predicted, but has not experimental ....Ultrafast photonic hammer: A new strategy to synthesise super-dense super-hard nanomaterials. We will develop a new way for laboratory synthesis of new classes of super-hard and super-dense materials at and above the extremely high temperature and density range currently accessible only in nuclear explosions. The ability of ultra-fast laser-induced phase transformations will be exploited aiming to form materials with exotic properties, which are theoretically predicted, but has not experimentally confirmed yet. Our new approach will have a profound interdisciplinary impact. The project will deliver underpinning knowledge, foremost practical expertise, and the prominent training of young researchers to secure Australia's international position among the leaders in the rapidly growing and competitive field of nanotechnology.Read moreRead less
Visualizing spin-related properties of functional nanostructures (for spintronics). This project contributes to undergraduate, postgraduate and postdoctoral research and training to encourage the pursuit of excellence, with:
- increased depth of knowledge in interdisciplinary research,
- a scientific environment providing access to research not otherwise in Australia,
- experience in the design, construction and development of scientific instruments.
Possible applications include high-speed ....Visualizing spin-related properties of functional nanostructures (for spintronics). This project contributes to undergraduate, postgraduate and postdoctoral research and training to encourage the pursuit of excellence, with:
- increased depth of knowledge in interdisciplinary research,
- a scientific environment providing access to research not otherwise in Australia,
- experience in the design, construction and development of scientific instruments.
Possible applications include high-speed magnetic filters, sensors, quantum transistors and spin qubits for quantum computers. The technological aspects of our project's outcomes offer real prospects of local development. The development of spin-polarized electron spectroscopy has great potential for existing applications in the surface science industry.
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Dual wavelength quantum dot light detectors. This project aims to develop technologies to fabricate advanced electronic materials based on gallium antimonide (GaSb), to explore their physics and use them in improved optoelectronic devices.
GaSb technology is in its infancy, therefore basic and applied research is needed to utilise these materials to their full potential for long wavelength photonic devices with unique promise in military and civilian applications: fire detection, missile and ....Dual wavelength quantum dot light detectors. This project aims to develop technologies to fabricate advanced electronic materials based on gallium antimonide (GaSb), to explore their physics and use them in improved optoelectronic devices.
GaSb technology is in its infancy, therefore basic and applied research is needed to utilise these materials to their full potential for long wavelength photonic devices with unique promise in military and civilian applications: fire detection, missile and surveillance systems, environmental monitoring, biology and medicine.
As an outcome, growth protocols for innovative device structures will be established, the structures' behaviour assessed and device fabrication and characterisation carried out and reported.
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Electron Emission from Diamond. Israel is emerging as an international hub of technology with one of the highest rates of R&D in the world. This collaborative project will access one of the world leading experts in diamond science and technology, Professor Alon Hoffman, to exploit the remarkable properties of diamond for a new generation of detectors and devices. Success in this project can lay the groundwork for tapping into the successful record of advanced technologies and venture capital fun ....Electron Emission from Diamond. Israel is emerging as an international hub of technology with one of the highest rates of R&D in the world. This collaborative project will access one of the world leading experts in diamond science and technology, Professor Alon Hoffman, to exploit the remarkable properties of diamond for a new generation of detectors and devices. Success in this project can lay the groundwork for tapping into the successful record of advanced technologies and venture capital funding that abound in Israel today. Read moreRead less
Centre for Quantum Computer Technology. Development of a quantum computer (QC) for massively parallel computing is one of the major challenges in science and engineering this century. Since 2000 the Centre has achieved two major breakthroughs in this field: constructing the key functional element of a silicon solid-state QC; and co-inventing a scheme for efficient linear optics QC. The proposed CoE aims to align these two nationally co-ordinated research programs with the world's existing comput ....Centre for Quantum Computer Technology. Development of a quantum computer (QC) for massively parallel computing is one of the major challenges in science and engineering this century. Since 2000 the Centre has achieved two major breakthroughs in this field: constructing the key functional element of a silicon solid-state QC; and co-inventing a scheme for efficient linear optics QC. The proposed CoE aims to align these two nationally co-ordinated research programs with the world's existing computer and IT industries to realise a fault-tolerant multiple qubit quantum processor with integrated control and qubit chips, and develop a scaleable optical quantum processor providing significant economic benefit to Australia.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL0992247
Funder
Australian Research Council
Funding Amount
$2,988,295.00
Summary
Advances at the frontiers of subatomic physics and cross-disciplinary applications of the associated techniques. The candidate is an international scientific leader, in terms of his own research, his responsibilities within the United States Department of Energy (DoE) and his role as Chair of the International Union of Pure and Applied Physics (IUPAP) Working Group on International Cooperation in Nuclear Physics. His return to South Australia to establish a major new research centre in the physi ....Advances at the frontiers of subatomic physics and cross-disciplinary applications of the associated techniques. The candidate is an international scientific leader, in terms of his own research, his responsibilities within the United States Department of Energy (DoE) and his role as Chair of the International Union of Pure and Applied Physics (IUPAP) Working Group on International Cooperation in Nuclear Physics. His return to South Australia to establish a major new research centre in the physical sciences will dramatically enhance the State's reputation in science and engineering, an essential component of its contribution to the nation's defence. It will underline Australia's commitment to contribute its share to advancing fundamental science. The involvement of senior researchers from fields as diverse as applied optics and mathematical biology will ensure that the opportunities for cross-disciplinary research are fully exploited.Read moreRead less
Optoelectronic properties of low-dimensional semiconductor systems and semiconductor nanostructures under terahertz free-electron laser radiation. The recent application of terahertz (THz) free-electron lasers (FELs) to scientific investigation into low-dimensional semiconductor systems and semiconductor nanostructures has opened up a new field of research in semiconductor optoelectronics. This project will conduct a joint experimental and theoretical study of how these novel systems interact w ....Optoelectronic properties of low-dimensional semiconductor systems and semiconductor nanostructures under terahertz free-electron laser radiation. The recent application of terahertz (THz) free-electron lasers (FELs) to scientific investigation into low-dimensional semiconductor systems and semiconductor nanostructures has opened up a new field of research in semiconductor optoelectronics. This project will conduct a joint experimental and theoretical study of how these novel systems interact with intense THz laser fields. Experimentally, we plan to use Beijing FELs in China to study optoelectronic properties in GaAs-and GaN based systems. Theoretically, we intend developing fundamental new approaches to theory of electron interactions with intense laser fields in semiconductors and relating theoretical results to experiments and experimental findings.Read moreRead less
Nanoclusters with Extraordinary Properties Made out of Ordinary Materials. Ultrafast laser deposition - a process pioneered by the Applicants - has already demonstrated record yields in the production of carbon-based nano-clustered materials with better control over the size of the nano-particles than any other process. This project aims to improve fundamental understanding of the ultra-fast laser deposition method of nano-fabrication through theoretical and experimental studies, which accurate ....Nanoclusters with Extraordinary Properties Made out of Ordinary Materials. Ultrafast laser deposition - a process pioneered by the Applicants - has already demonstrated record yields in the production of carbon-based nano-clustered materials with better control over the size of the nano-particles than any other process. This project aims to improve fundamental understanding of the ultra-fast laser deposition method of nano-fabrication through theoretical and experimental studies, which accurately correlate the ablation conditions to the structural, electronic, magnetic and optical properties of resulting nano-particles. The results will be applied to efficiently produce nano-clustered materials with tuneable properties for a wide range of new technologies such as spintronics, biophotonics, and nanoclinics.Read moreRead less