Atomic tests of unification theories. Although the standard model of particle physics has withstood decades of intensive experimental tests, it is widely believed to be merely a low-energy manifestation of a "true" theory that unifies the four forces of nature. While some searches for new physics beyond the standard model are performed at high-energy particle accelerators, a very sensitive probe can be done at low energies in atomic and molecular measurements of weak interaction effects. This pr ....Atomic tests of unification theories. Although the standard model of particle physics has withstood decades of intensive experimental tests, it is widely believed to be merely a low-energy manifestation of a "true" theory that unifies the four forces of nature. While some searches for new physics beyond the standard model are performed at high-energy particle accelerators, a very sensitive probe can be done at low energies in atomic and molecular measurements of weak interaction effects. This project is devoted to a theoretical investigation of weak interaction effects in atoms, molecules, and nuclei. It will provide improved tests of unified theories.Read moreRead less
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
The New Dimensions of the Quantum Universe. This Fellowship will help build and strengthen significant world-class research capacity at the frontier of fundamental science. More students will be motivated to pursue careers in science, increasing the number of talented, world-class science graduates in Australia. It will forge strong research links both locally and internationally so as to enhance existing networks and create new ones. It will greatly enhance Australia's standing in particle phys ....The New Dimensions of the Quantum Universe. This Fellowship will help build and strengthen significant world-class research capacity at the frontier of fundamental science. More students will be motivated to pursue careers in science, increasing the number of talented, world-class science graduates in Australia. It will forge strong research links both locally and internationally so as to enhance existing networks and create new ones. It will greatly enhance Australia's standing in particle physics, the epitome of Big Science, and garner new respect from one of the world's most influential scientific communities. Having this kind of world-class research in Australia, will also help foster public education and advance the public understanding of fundamental science.
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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
Radiation protection for space, aviation, and terrestrial applications: the development of novel radiation detectors and computational techniques. Personnel in space, aviation, and terrestrial applications may be exposed to potentially harmful levels of densely ionising radiation. This project will produce improved radiation detectors and computational techniques, addressing needs in the prediction and assessment of equivalent dose in these applications. The "preventative healthcare" priority go ....Radiation protection for space, aviation, and terrestrial applications: the development of novel radiation detectors and computational techniques. Personnel in space, aviation, and terrestrial applications may be exposed to potentially harmful levels of densely ionising radiation. This project will produce improved radiation detectors and computational techniques, addressing needs in the prediction and assessment of equivalent dose in these applications. The "preventative healthcare" priority goal of the National Research Priority "Promoting and Maintaining Good Health" will be addressed, serving to reduce the risk to personnel involved in such activities. This research will also enhance Australia's international reputation in this field, stimulate local expertise, and create a critical mass of researchers in this field. Read moreRead less
Searching for Supersymmetry in the Universe with the A Toroidal Lagre Hadron Collider ApparatuS (ATLAS) experiment at the Large Hadron Collider. Australian researchers have been involved with the A Toroidal Lagre Hadron Collider ApparatuS (ATLAS) experiment at the Large Hadron Collider since the early 1990's. They have had significant roles in ATLAS hardware design and construction, software development, and in the deployment of a data computing grid, thereby paving the way for groundbreaking di ....Searching for Supersymmetry in the Universe with the A Toroidal Lagre Hadron Collider ApparatuS (ATLAS) experiment at the Large Hadron Collider. Australian researchers have been involved with the A Toroidal Lagre Hadron Collider ApparatuS (ATLAS) experiment at the Large Hadron Collider since the early 1990's. They have had significant roles in ATLAS hardware design and construction, software development, and in the deployment of a data computing grid, thereby paving the way for groundbreaking discoveries surrounding the fundamental laws and origin of our universe. By performing a search for Higgs bosons, required in many models of particle physics but which have so far not been observed, this research embodies the final step on this road to discovery. The huge publicity surrounding the discovery potential at the Large Hadron Collider will raise the international awareness and stature of basic research in Australia.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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High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high- ....High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high-energy experiments. This project will satisfy that role. The application of particle detector expertise to state-of-the-art X-ray imaging detectors for the Australian Synchrotron and medical imaging is a perfect example of fundamental science tools applied to other fields. Australian Synchrotron experiments stand to gain much.Read moreRead less
High energy neutrino astrophysics together with accretion flows into black holes. Neutrinos are very weakly interacting elementary particles that are opening a new view on astrophysical objects such as supernovae and active galactic nuclei (neutrino astronomy). Studies of astrophysical neutrino production, propagation and terrestrial detection will be made. This will shed light on the astrophysics of the sources as well as probing propagation effects such as neutrino oscillations. A distinct pro ....High energy neutrino astrophysics together with accretion flows into black holes. Neutrinos are very weakly interacting elementary particles that are opening a new view on astrophysical objects such as supernovae and active galactic nuclei (neutrino astronomy). Studies of astrophysical neutrino production, propagation and terrestrial detection will be made. This will shed light on the astrophysics of the sources as well as probing propagation effects such as neutrino oscillations. A distinct programme will study a large discrepancy in the energy balance for matter accreting into a black hole. Previous work of Buzzi and Hines will be extended to investigate whether plasma wave energy carried into the black hole can explain the discrepancy. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453432
Funder
Australian Research Council
Funding Amount
$257,250.00
Summary
Support for the Australian Experimental High Energy Physics Program. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest.The ATLAS and Belle experime ....Support for the Australian Experimental High Energy Physics Program. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest.The ATLAS and Belle experiments probe two of the most significant questions in fundamental physics: what is the origin of mass, and why do we live in a universe composed of matter rather than antimatter? This proposal seeks support to maintain access to the international high energy physics program in Europe and Japan.Read moreRead less