Characterising Nuclei Far from Stability With a Novel Recoil Spectrometer. A high sensitivity detector system for use in conjuction with a superconducting solenoidal transporter will be developed for gamma-ray and conversion spectroscopy of neutron-deficient nuclei. The technology will be optimised for near-symmetric heavy ion reactions and applied initially to the characterisation of shape co-existence in the light lead isotopes. These provide a major testing ground for the development of mean- ....Characterising Nuclei Far from Stability With a Novel Recoil Spectrometer. A high sensitivity detector system for use in conjuction with a superconducting solenoidal transporter will be developed for gamma-ray and conversion spectroscopy of neutron-deficient nuclei. The technology will be optimised for near-symmetric heavy ion reactions and applied initially to the characterisation of shape co-existence in the light lead isotopes. These provide a major testing ground for the development of mean-field theories used to predict the stability of heavy nuclei.Read moreRead less
Developing and exploiting a beam of exotic neutron halo nuclei: probing quantum coherence and decoherence at the femtoscale. Developing an Australian rare isotope beam capability with unique features will be a breakthrough in Australia's capability in science. It will create new opportunities for local research with radioactive isotope beams, a field being vigorously developed world-wide, as new access to short-lived radioactive isotopes will open up many opportunities in fundamental research an ....Developing and exploiting a beam of exotic neutron halo nuclei: probing quantum coherence and decoherence at the femtoscale. Developing an Australian rare isotope beam capability with unique features will be a breakthrough in Australia's capability in science. It will create new opportunities for local research with radioactive isotope beams, a field being vigorously developed world-wide, as new access to short-lived radioactive isotopes will open up many opportunities in fundamental research and applications. The experience and strong international linkages from this project will facilitate the longer-term use of future large-scale international facilities. This project will also build links with other areas of research strength in Australia, and keep us at the cutting-edge in research and training in nuclear science, a matter of national importance.Read moreRead less
Probing the Universe with gravitational waves: from cutting-edge technology to astronomy. The direct detection of Einstein's elusive gravitational waves will not only confirm one of the most important theories in physics, it will unleash a new form of radiation (in addition to electromagnetic) with which to study the Universe. Our participation in this quest continues Australia's role in the vanguard of new astronomy and its exploitation. This proposal will produce scientists highly trained in ....Probing the Universe with gravitational waves: from cutting-edge technology to astronomy. The direct detection of Einstein's elusive gravitational waves will not only confirm one of the most important theories in physics, it will unleash a new form of radiation (in addition to electromagnetic) with which to study the Universe. Our participation in this quest continues Australia's role in the vanguard of new astronomy and its exploitation. This proposal will produce scientists highly trained in areas of national priority, including frontier technologies such as photonics and smart information use through GRID computing. Developing ways to build instruments of almost unimaginable sensitivity fosters innovation leading to spin-offs into other areas of optical sensing - fundamental research resulting in economic benefit.Read moreRead less
Alpha-particle cluster structure in light nuclei: helping and hindering fusion? A new, efficient detector system will be designed and built to answer a question never before asked - can the special structures of carbon, resembling three alpha-particles, assist rather than hinder the process of fusion with heavy nuclei? This question has arisen through my recent work published in Nature, which showed that in reactions with heavy nuclei, paradoxically both fusion and break-up into alpha-particles ....Alpha-particle cluster structure in light nuclei: helping and hindering fusion? A new, efficient detector system will be designed and built to answer a question never before asked - can the special structures of carbon, resembling three alpha-particles, assist rather than hinder the process of fusion with heavy nuclei? This question has arisen through my recent work published in Nature, which showed that in reactions with heavy nuclei, paradoxically both fusion and break-up into alpha-particles are more likely for carbon than for neighbouring nuclei. These results defy interpretation within the standard theory of nuclear fusion. The project will help to maintain Australia's world-leading position in the study of nuclear fusion.
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Dynamic Correlations and Coherence Effects in Two-Electron Emission Processes. The electronic structure and properties of matter are determined by the correlated motion of electrons. Thus an understanding of this quantum mechanical many-body problem is central to our understanding of nature. We will apply laser-based quantum-state-selective techniques and advanced instrumentation to uncover new phenomena in many-body spin-correlated electron dynamics, quantum coherence and entanglement. The resu ....Dynamic Correlations and Coherence Effects in Two-Electron Emission Processes. The electronic structure and properties of matter are determined by the correlated motion of electrons. Thus an understanding of this quantum mechanical many-body problem is central to our understanding of nature. We will apply laser-based quantum-state-selective techniques and advanced instrumentation to uncover new phenomena in many-body spin-correlated electron dynamics, quantum coherence and entanglement. The resulting benchmark data will force significant developments in theory, extending its predictive power to drive advancements in areas ranging from industrial and astrophysical plasmas, gas discharges, lasers, and planetary atmospheres, to nanoscale electronic and spintronic devices.Read moreRead less
Pushing the frontiers of gravitational wave science: from technology to astrophysics. The direct detection of Einstein's elusive gravitational waves will not only confirm one of the most important theories in physics, it will unleash a new form of radiation (in addition to electromagnetic) with which to study the Universe. Our participation in this quest continues Australia's role in the vanguard of new astronomy and its exploitation. This proposal will produce scientists highly trained in ar ....Pushing the frontiers of gravitational wave science: from technology to astrophysics. The direct detection of Einstein's elusive gravitational waves will not only confirm one of the most important theories in physics, it will unleash a new form of radiation (in addition to electromagnetic) with which to study the Universe. Our participation in this quest continues Australia's role in the vanguard of new astronomy and its exploitation. This proposal will produce scientists highly trained in areas of national priority, including frontier technologies such as photonics and smart information use through GRID computing. Developing ways to build instruments of almost unimaginable sensitivity fosters innovation leading to spin-offs into other areas of optical sensing - fundamental research resulting in economic benefit.Read moreRead less
Across the Gravitational Wave Spectrum. Violent astrophysical events in the universe emit gravitational waves across a spectrum from mHz to kHz, producing an infinitesimal?but detectable'strain in space-time itself. Like high energy physics projects, gravitational wave detection involves giant multi million dollar research facilities and extensive international collaboration. This project will develop ideas, equipment and algorithms which will enhance the performance of both high frequency (gro ....Across the Gravitational Wave Spectrum. Violent astrophysical events in the universe emit gravitational waves across a spectrum from mHz to kHz, producing an infinitesimal?but detectable'strain in space-time itself. Like high energy physics projects, gravitational wave detection involves giant multi million dollar research facilities and extensive international collaboration. This project will develop ideas, equipment and algorithms which will enhance the performance of both high frequency (ground) and low frequency (space) based laser interferometer type detectors, and see Australia expand its already important role in searching for nature's most elusive signals.Read moreRead less
Plutonium - A new tracer of sediment transport into the Great Barrier Reef Lagoon. This work will quantify one of the most controversial threats to the Great Barrier Reef Marine Park, namely the amount of sediment reaching the reef as a consequence of human activities. It will have economic implications for this major Australian tourist attraction, as well as the commercial fishing and agricultural and horticultural industries in the region. The direct economic value associated with these indust ....Plutonium - A new tracer of sediment transport into the Great Barrier Reef Lagoon. This work will quantify one of the most controversial threats to the Great Barrier Reef Marine Park, namely the amount of sediment reaching the reef as a consequence of human activities. It will have economic implications for this major Australian tourist attraction, as well as the commercial fishing and agricultural and horticultural industries in the region. The direct economic value associated with these industries exceeds $1 billion per annum, and around 1 million people visit the inshore areas every year. Management of the park will benefit through improved understanding of the transport of sediment from the rivers to the lagoon and inner reef areas, and the fraction of the sediment attributable to anthropogenic practices. Read moreRead less
Nanorheology: Hydrodynamic Slip in Newtonian Fluids. Understanding fluid flow across a surface is essential to a great number of technologies. For over one hundred years it has been assumed that the layer of fluid adjacent to the solid moves with the solid, this is known as the no-slip boundary condition. Recently direct force balance measurements of aqueous Newtonian solutions have indicated the presence of boundary slip. Using a newly developed nanorheology technique we will systematically inv ....Nanorheology: Hydrodynamic Slip in Newtonian Fluids. Understanding fluid flow across a surface is essential to a great number of technologies. For over one hundred years it has been assumed that the layer of fluid adjacent to the solid moves with the solid, this is known as the no-slip boundary condition. Recently direct force balance measurements of aqueous Newtonian solutions have indicated the presence of boundary slip. Using a newly developed nanorheology technique we will systematically investigate the conditions that control boundary slip. This information will be used to quantify, model and control boundary slip, progressing the fields of microfluidics, particle deposition, and colloid stability.Read moreRead less
Exposure dating with manganese-53, neon-21 and beryllium-10: a new toolkit for studying long-term landscape evolution. Australia today is the driest inhabited continent but this was not always the case. Tens of millions of years ago the climate of Australia was considerably wetter. Then, several million years ago, aridity in Australia developed producing most of the desert features of the red Centre that we see today. The age of our deserts and other arid features are not, however, well known. T ....Exposure dating with manganese-53, neon-21 and beryllium-10: a new toolkit for studying long-term landscape evolution. Australia today is the driest inhabited continent but this was not always the case. Tens of millions of years ago the climate of Australia was considerably wetter. Then, several million years ago, aridity in Australia developed producing most of the desert features of the red Centre that we see today. The age of our deserts and other arid features are not, however, well known. This project will determine the age of desertification in Australia, thereby enhancing our understanding of such processes and the response of our landscape to changing climate.
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