High-performance computational data-mining techniques for feature detection in complex time series from large-scale, networked plasma experiments. Terabytes of data are gathered from large experimental facilities as complex time-series. Analysis of these data is daunting, especially when they involve high-dimensional spectral or image arrays. We will develop high-performance computational techniques for dimension reduction, efficient data-mining, and experimental control, using as an initial ta ....High-performance computational data-mining techniques for feature detection in complex time series from large-scale, networked plasma experiments. Terabytes of data are gathered from large experimental facilities as complex time-series. Analysis of these data is daunting, especially when they involve high-dimensional spectral or image arrays. We will develop high-performance computational techniques for dimension reduction, efficient data-mining, and experimental control, using as an initial target the H-1NF plasma fusion MNRF at the ANU and its >100 GB/year data stream. The techniques will immediately provide Australian researchers with unique tools for collaboration in international research to develop fusion as a low-emissions source of electricity, and will be applicable to complex time-series analysis in other areas of science, medicine, and defence.Read moreRead less
Development of a quantum computer based on solid-state optical impurity sites. The use of optical impurity sites in solid-state hosts as a basis for a quantum computer will be investigated. This project will experimentally demonstrate and characterize all the functions necessary for the operation of a scalable quantum computer. A significant advantage of the current approach is that all these functions can be performed optically, circumventing the need for the complex fabrication found in othe ....Development of a quantum computer based on solid-state optical impurity sites. The use of optical impurity sites in solid-state hosts as a basis for a quantum computer will be investigated. This project will experimentally demonstrate and characterize all the functions necessary for the operation of a scalable quantum computer. A significant advantage of the current approach is that all these functions can be performed optically, circumventing the need for the complex fabrication found in other solid-state quantum computing schemes.Read moreRead less
CP Symmetry Violation in Strange B Meson decays at the Belle Experiment. This research exploits very recent development in high energy physics to formulate new tests on the limits of our understanding of matter-antimatter symmetry violation in our universe. The researchers have internationally recognised expertise in distributed Grid computing, which has been pioneered by the high energy physics community, and is now finding wide deployment in other scientific fields. Deployment of a Belle Data ....CP Symmetry Violation in Strange B Meson decays at the Belle Experiment. This research exploits very recent development in high energy physics to formulate new tests on the limits of our understanding of matter-antimatter symmetry violation in our universe. The researchers have internationally recognised expertise in distributed Grid computing, which has been pioneered by the high energy physics community, and is now finding wide deployment in other scientific fields. Deployment of a Belle Data Grid will provide true international interoperability with national Grid infrastructure, and substantial opportunity for expanded international collaboration on eresearch infrastructure. High Energy Physics also provides post-graduate students with the best possible exposure to leading international researchers.Read moreRead less
Ultra-high density permanent and/or erasable optical memory in photorefractive media formed by ultrafast laser pulses. A possibility to form tree-dimensional 10Tb-density optical memory based on permanent modification, or damage, of transparent dielectrics, using powerful femtosecond laser pulses has already been demonstrated by the Applicants. This project aims to improve the fundamental understanding of ultrafast laser formation of nano-bits using unique ability of photorefractive materials t ....Ultra-high density permanent and/or erasable optical memory in photorefractive media formed by ultrafast laser pulses. A possibility to form tree-dimensional 10Tb-density optical memory based on permanent modification, or damage, of transparent dielectrics, using powerful femtosecond laser pulses has already been demonstrated by the Applicants. This project aims to improve the fundamental understanding of ultrafast laser formation of nano-bits using unique ability of photorefractive materials to reversible change and the refractive index. We aim to find ways for controlling the storage time, density and the writing-reading-erasing rate without inducing damage in the material. The results will be applied to efficient formation of high-speed, high density, write-read-erase 3D optical memory for applications in the information technology.
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The development of Data Grids for High Energy Physics. Data Grids have developed world-wide interest as a means of enabling
geographically separated groups to collaborate and share data and computing
resources. Their use is particularly important to Australians.
High Energy Physics has been, and will continue to be a test-bed for these
technologies. Through our involvement with the state-of-the-art experiments
at BELLE and ATLAS, we plan to participate in the World-wide Data Grid
resear ....The development of Data Grids for High Energy Physics. Data Grids have developed world-wide interest as a means of enabling
geographically separated groups to collaborate and share data and computing
resources. Their use is particularly important to Australians.
High Energy Physics has been, and will continue to be a test-bed for these
technologies. Through our involvement with the state-of-the-art experiments
at BELLE and ATLAS, we plan to participate in the World-wide Data Grid
research and development effort and deploy novel techniques to significantly enhance their
usefulness to Australians.Read moreRead less
A theoretical understanding of galaxy assembly and black hole evolution across cosmic time. This research will establish Australia as a centre for cutting edge galaxy formation modelling. To achieve its science goals, we will make publicly available the world's largest cosmological simulation of dark matter and galaxy evolution. We will design and deploy an online web portal within which custom galaxy formation models can be constructed by anyone in the community for their own work. Support fo ....A theoretical understanding of galaxy assembly and black hole evolution across cosmic time. This research will establish Australia as a centre for cutting edge galaxy formation modelling. To achieve its science goals, we will make publicly available the world's largest cosmological simulation of dark matter and galaxy evolution. We will design and deploy an online web portal within which custom galaxy formation models can be constructed by anyone in the community for their own work. Support for this proposal will strengthen theoretical astronomy in Australia at a time when increased theoretical infrastructure is needed to fully capitalise on Australia's significant observational investments.
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Nonlinear nanophotonics. This project will support world-leading research in nonlinear nanophotonics. It will develop theoretically and demonstrate experimentally novel concepts for confining and manipulating light in specially designed structures, making an essential step towards the creation of nanoscaled optical devices for storage, memory, and sensing. These developments will underpin the next generation of high-performance optical networks promising to revolutionize global communications. T ....Nonlinear nanophotonics. This project will support world-leading research in nonlinear nanophotonics. It will develop theoretically and demonstrate experimentally novel concepts for confining and manipulating light in specially designed structures, making an essential step towards the creation of nanoscaled optical devices for storage, memory, and sensing. These developments will underpin the next generation of high-performance optical networks promising to revolutionize global communications. This research program will keep Australia at the forefront of international research and provide training for students in breakthrough applications of nanophotonics and nanotechnology, contributing to the uptake of frontier technologies by Australian industries.Read moreRead less
Manipulation and Shaping of Light in the Far-Field using Advanced Fresnel Fibres. This project will focus on developing and understanding further the recent invention of the Fresnel fibre, which is designed to overcome diffraction from the end of an optical fibre. More sophisticated designs and combinations will allow arbitrary shaping of the optical field exiting an optical fibre for numerous applications. The physical basis for such phenomena to be realised is the efficient degree of coherent ....Manipulation and Shaping of Light in the Far-Field using Advanced Fresnel Fibres. This project will focus on developing and understanding further the recent invention of the Fresnel fibre, which is designed to overcome diffraction from the end of an optical fibre. More sophisticated designs and combinations will allow arbitrary shaping of the optical field exiting an optical fibre for numerous applications. The physical basis for such phenomena to be realised is the efficient degree of coherent scattering possible in air-material fibre such as air-silica photonic crystal fibres. In conjunction advanced characterisation techniques will be developed.Read moreRead less
Hypersensitisation and Patterned Photosensitivity in Glass. Recent developments involving holographically patterned photosensitivity in glass-based optical waveguides developed by our group can be extended to fabricate complex two-dimensional structures including planar waveguide photonic bandgap devices for applications in telecommunications, sensing and signal processing. These will include novel grating-array based 2-D DFB lasers and filters in rare-earth doped planar waveguides. Novel etchin ....Hypersensitisation and Patterned Photosensitivity in Glass. Recent developments involving holographically patterned photosensitivity in glass-based optical waveguides developed by our group can be extended to fabricate complex two-dimensional structures including planar waveguide photonic bandgap devices for applications in telecommunications, sensing and signal processing. These will include novel grating-array based 2-D DFB lasers and filters in rare-earth doped planar waveguides. Novel etching techniques to be used to enhance index contrast, as well as to characterise such devices, will be developed based on our recent observation of hydrogen-enhanced etching of glass. Such methods could potentially be applicable to not only photonic technologies but also semiconductor lithography of oxides.Read moreRead less
A deep survey for compact structure in the nearby universe: key science for the upgraded Australian Long Baseline Array. This project uses advances in ICT to build a national and international network of facilities that includes existing telescopes primarily on the east coast of Australia, as well as planned facilities in Western Australia and New Zealand. One of these facilities, the New Technology Demonstrator, is a crucial part of Australia's roadmap to the Square Kilometre Array. The SKA-r ....A deep survey for compact structure in the nearby universe: key science for the upgraded Australian Long Baseline Array. This project uses advances in ICT to build a national and international network of facilities that includes existing telescopes primarily on the east coast of Australia, as well as planned facilities in Western Australia and New Zealand. One of these facilities, the New Technology Demonstrator, is a crucial part of Australia's roadmap to the Square Kilometre Array. The SKA-related science and technology demonstrations we will undertake as part of this project will contribute to Australia's bid to host this $US1b instrument. This project cements a significant Trans-Tasman collaboration and brings together researchers in astrophysics and ICT to give Australia a leading position in the field of eVLBI.Read moreRead less