Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989347
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
CYCLOPS - A Better Way to Find Extrasolar Planets. The primary scientific driver for this new facility is the search for planets orbiting other stars. Australian astronomers, and the Anglo-Australian Telescope, have played a leading role in this new frontier for astronomy, detecting 25 of the 250-odd extrasolar planets known to orbit nearby stars. The CYCLOPS project brings together a team of leading Australian astronomers to build on this track record with a new facility that further advances A ....CYCLOPS - A Better Way to Find Extrasolar Planets. The primary scientific driver for this new facility is the search for planets orbiting other stars. Australian astronomers, and the Anglo-Australian Telescope, have played a leading role in this new frontier for astronomy, detecting 25 of the 250-odd extrasolar planets known to orbit nearby stars. The CYCLOPS project brings together a team of leading Australian astronomers to build on this track record with a new facility that further advances Australia's capabilities in both this field, and several other high-profile astronomical endeavours: including the study of seismology in stellar interiors, the detailed measurement of elemental abundances in stars throughout our Galaxy, and the mapping of spot features on the surfaces of stars.Read moreRead less
Nanoindentation-induced Phase Transformations and Physical Property Changes in Semiconductors. The motivation for this study derives from recent findings of intriguing phase and structural changes induced in semiconductors under a small indenter when it is pressed into the surface. Using an array of sophisticated techniques, in this study we plan to explore for the first time the structural changes that can be induced in semiconductors on the nanoscale and to study what novel properties, partic ....Nanoindentation-induced Phase Transformations and Physical Property Changes in Semiconductors. The motivation for this study derives from recent findings of intriguing phase and structural changes induced in semiconductors under a small indenter when it is pressed into the surface. Using an array of sophisticated techniques, in this study we plan to explore for the first time the structural changes that can be induced in semiconductors on the nanoscale and to study what novel properties, particularly electrical, such nanoscale regions may have. Detailed nanoindentation studies will focus on understanding and exploiting deformation of silicon, to open up an exciting prospect: the development of an entirely new, ultra-high-density information storage process.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL0992306
Funder
Australian Research Council
Funding Amount
$2,753,841.00
Summary
Nanowire Quantum Structures for Next Generation Optoelectronics. This innovative project on quantum nanowire optoelectronics will bring international kudos to Australian science in a hot research area of immense international interest, allow us to build new capabilities in nanotechnology, strengthen international linkages and lead to training of a world class high tech work force for Australian industries. This project has the potential to lead to fundamental discoveries and technologies of imm ....Nanowire Quantum Structures for Next Generation Optoelectronics. This innovative project on quantum nanowire optoelectronics will bring international kudos to Australian science in a hot research area of immense international interest, allow us to build new capabilities in nanotechnology, strengthen international linkages and lead to training of a world class high tech work force for Australian industries. This project has the potential to lead to fundamental discoveries and technologies of immense international and industrial interest. In addition to high impact publications, this project has the potential to lead to high tech start up companies and patentable technologies of benefit to Australian industry. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347466
Funder
Australian Research Council
Funding Amount
$262,000.00
Summary
Australian e-Astronomy. An explosion in the rate of data acquisition in disciplines such as astronomy will require new database structures and management systems. Scientists require fast access and analysis of data from many different telescopes, instruments and theoretical modelling packages. The new directions being explored internationally are based on datagrids, where individual nodes house the physical data archives and expertise, but are networked into a unified system, providing open a ....Australian e-Astronomy. An explosion in the rate of data acquisition in disciplines such as astronomy will require new database structures and management systems. Scientists require fast access and analysis of data from many different telescopes, instruments and theoretical modelling packages. The new directions being explored internationally are based on datagrids, where individual nodes house the physical data archives and expertise, but are networked into a unified system, providing open access to all astronomers. Australian e-Astronomy will provide Phase 1 of a project to develop an astronomy datagrid in Australia, linking to the powerful programs which have just commenced in Europe, UK and the USA.Read moreRead less
Dynamics of Nuclear Fusion: Evolution Through a Complex Multi-Dimensional Landscape. The key questions in the fusion of heavy nuclei form an interlocking puzzle, which can be resolved using our recently developed analysis concepts and measurement techniques. The newly completed, unique, and highly efficient superconducting fusion product separator, together with Australian's Heavy Ion Accelerator, will be used to unlock the puzzle and reveal how fusing nuclei evolve in a multi-dimensional landsc ....Dynamics of Nuclear Fusion: Evolution Through a Complex Multi-Dimensional Landscape. The key questions in the fusion of heavy nuclei form an interlocking puzzle, which can be resolved using our recently developed analysis concepts and measurement techniques. The newly completed, unique, and highly efficient superconducting fusion product separator, together with Australian's Heavy Ion Accelerator, will be used to unlock the puzzle and reveal how fusing nuclei evolve in a multi-dimensional landscape. This will impact on the emerging fields of superheavy element formation, physics with rare isotope beams, and on coupling-assisted quantum tunnelling. This project will maintain Australia's world-leading position in the current race to develop a quantitative understanding of fusion.
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Development of high performance wide-bandgap polar oxide electronic and optoelectronic devices. The research and development of high performance electronic and optoelectronic devices based on polar semiconductors have numerous practical applications in future communication systems and power electronic network. This project aims to generate exciting breakthrough science for novel polar oxide devices. The technologies developed through this project may lead to immediate applications and commercial ....Development of high performance wide-bandgap polar oxide electronic and optoelectronic devices. The research and development of high performance electronic and optoelectronic devices based on polar semiconductors have numerous practical applications in future communication systems and power electronic network. This project aims to generate exciting breakthrough science for novel polar oxide devices. The technologies developed through this project may lead to immediate applications and commercialization of high performance devices in sensing, detection and communication, bringing enormous economic benefit for the Nation. The international collaboration will provide invaluable resources for both scientific research and technology development and keep Australia at the forefront in this field.Read moreRead less
Low temperature fabrication of silicon-based thin film transistors (TFTs) for flat panel displays - an entirely new approach. This project represents an entirely new approach to low temperature crystallization of amorphous silicon, and its application to TFT fabrication in flat panel displays, and involves a partnership with the Australian high-tech company, WRiota. The research is in a field of high national priority, namely nanotechnology, since the technology is based on materials modificati ....Low temperature fabrication of silicon-based thin film transistors (TFTs) for flat panel displays - an entirely new approach. This project represents an entirely new approach to low temperature crystallization of amorphous silicon, and its application to TFT fabrication in flat panel displays, and involves a partnership with the Australian high-tech company, WRiota. The research is in a field of high national priority, namely nanotechnology, since the technology is based on materials modification at the nanoscale by nanoindentation. This project will further provide valuable opportunities for a number of research students and ECRs to gain experience in both the industrial and academic worlds and skills needed for Australia's nanotechnology workforce.Read moreRead less
Nonlinear atom optics of Bose-Einstein condensates in optical lattices. When a new state of matter - Bose-Einstein condensate - is trapped in a periodic potential created by light, it forms a unique, reconfigurable nano-scale system with unprecedented control over its properties. Its behaviour ranges from quantum to classical, from linear to nonlinear, and from continuous to discrete. This project aims to develop a theory for the nonlinear localization, transport, and excitation of BEC in the op ....Nonlinear atom optics of Bose-Einstein condensates in optical lattices. When a new state of matter - Bose-Einstein condensate - is trapped in a periodic potential created by light, it forms a unique, reconfigurable nano-scale system with unprecedented control over its properties. Its behaviour ranges from quantum to classical, from linear to nonlinear, and from continuous to discrete. This project aims to develop a theory for the nonlinear localization, transport, and excitation of BEC in the optical lattices. Its outcome will provide an important assessment of the feasibility of the proposed use of the BEC in optical lattices in quantum computing, information storage, precision measurements, and nanotechnology.
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