Data-driven monitoring of raceway dynamics in ironmaking blast furnaces. Raceway dynamics in ironmaking blast furnaces affect operational stability and cost considerably, yet their dynamic behaviour has not been well monitored online. The project aims to develop a data-driven model for monitoring the internal state of gas-solid-powder reacting flow in the raceway and predicting raceway anomalies online. It will be achieved by combining particle-fluid numerical simulations with data processing an ....Data-driven monitoring of raceway dynamics in ironmaking blast furnaces. Raceway dynamics in ironmaking blast furnaces affect operational stability and cost considerably, yet their dynamic behaviour has not been well monitored online. The project aims to develop a data-driven model for monitoring the internal state of gas-solid-powder reacting flow in the raceway and predicting raceway anomalies online. It will be achieved by combining particle-fluid numerical simulations with data processing and reduced-order state observer, supported by lab/plant experiments, and collaborating with two industry partners from coal and steel industries. The project outcomes including codes, models and raceway control strategies can help promote Australian metallurgical coal's global markets and ultimately the Australian economy.Read moreRead less
Stawell Underground Physics Laboratory: Dark matter detector development. This project aims to develop ultra-sensitive detector technology essential for SABRE, a Northern and Southern Hemisphere dual-detector experiment. The SABRE facilities operate to directly detect galactic dark matter. Dark matter makes up 23% of the observable universe but the evidence for its existence is indirect. The direct detection of dark matter would be a discovery on par with gravitational waves and the Higgs boson. ....Stawell Underground Physics Laboratory: Dark matter detector development. This project aims to develop ultra-sensitive detector technology essential for SABRE, a Northern and Southern Hemisphere dual-detector experiment. The SABRE facilities operate to directly detect galactic dark matter. Dark matter makes up 23% of the observable universe but the evidence for its existence is indirect. The direct detection of dark matter would be a discovery on par with gravitational waves and the Higgs boson. This project is an opportunity for Australian research to continue to lead the way in the biggest scientific discoveries of the century and provides opportunities for Australian science in numerous fields ranging from biology to fundamental physics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100235
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Interfacial mapping facility. New electronic materials and devices impact on everyday life in areas such as photovoltaics, biotechnology and healthcare. This facility will provide researchers with the unique capability of mapping both the structure and electronic properties of materials on the nanoscale. It will be an essential tool for developing new electronics based on nanotechnology.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100042
Funder
Australian Research Council
Funding Amount
$621,834.00
Summary
Australian dark matter detector for high mass axions. This project aims to provide the necessary equipment to allow an Australian Dark Matter Axion Haloscope, with significantly increased sensitivity by providing a milliKelvin environment and a 14 T magnet to drive axion-to-photon conversions. Dark matter is a fundamental component of the universe yet the nature of its composition is still unknown. There is growing evidence that it is comprised of axions, a low energy, weakly interacting particl ....Australian dark matter detector for high mass axions. This project aims to provide the necessary equipment to allow an Australian Dark Matter Axion Haloscope, with significantly increased sensitivity by providing a milliKelvin environment and a 14 T magnet to drive axion-to-photon conversions. Dark matter is a fundamental component of the universe yet the nature of its composition is still unknown. There is growing evidence that it is comprised of axions, a low energy, weakly interacting particle. The precision measurement tools developed by this project will have the potential to contribute both to the economy, via commercialisation, and to national security, via future applications to radar, communication and the development of engineered quantum systems.Read moreRead less
Recoil spectroscopy of metastable nuclei far from stability. A unique recoil spectrometer has been developed with a sensitivity superior to competing international devices. It will be used to study the decay of long-lived states in neutron-deficient nuclei. The resulting ability to determine the quantum numbers of nuclear excited states will provide important information to test theories of nuclear matter.
Superdeformed nuclei and their decay: challenging nuclear models and probing quantum tunnelling. Nuclear superdeformation, where the atomic nucleus adopts an elongated, ellipsoidal shape and can undergo rapid rotation, offers a fascinating opportunity to study quantum mechanical effects in a system where single-particle and collective regimes overlap. The superdeformed shape itself is a spectacular example of collective motion in a mesoscopic system, while the rapid change to a sperhical shape ....Superdeformed nuclei and their decay: challenging nuclear models and probing quantum tunnelling. Nuclear superdeformation, where the atomic nucleus adopts an elongated, ellipsoidal shape and can undergo rapid rotation, offers a fascinating opportunity to study quantum mechanical effects in a system where single-particle and collective regimes overlap. The superdeformed shape itself is a spectacular example of collective motion in a mesoscopic system, while the rapid change to a sperhical shape is an excellent example of quantum-assisted tunnelling. The results of this project will shed light on this important process and provide a stringent test of our understanding of the nucleus.Read moreRead less
Isomers as Probes of Nuclear Structure and Sources of Energetic Photons. The aim is to study exotic long-lived states in nuclei using accelerator facilities in Australia and overseas. This involves the development of sensitive instrumentation and will lead to a new understanding of how such states are formed, of how they may be used to identify the structure of exotic nuclei, and on the limits of stability of nuclei in general. Isomers represent a special form of nuclear matter and they play a r ....Isomers as Probes of Nuclear Structure and Sources of Energetic Photons. The aim is to study exotic long-lived states in nuclei using accelerator facilities in Australia and overseas. This involves the development of sensitive instrumentation and will lead to a new understanding of how such states are formed, of how they may be used to identify the structure of exotic nuclei, and on the limits of stability of nuclei in general. Isomers represent a special form of nuclear matter and they play a role in the formation of the elements in stellar nucleosynthesis. Stimulated isomer decay may ultimately lead to new forms of energy storage and gamma-ray lasers.Read moreRead less
Quantum-number purity and limits to the formation of nuclear K-isomers. This internationally competitive research will result in new knowledge and the substantiation of Australian research in the nuclear structure area, as well as adding to our role in international scientific collaborations. The research is an important component of the local expertise in nuclear science established using Australian facilities which provide the major training ground for basic research, a variety of application ....Quantum-number purity and limits to the formation of nuclear K-isomers. This internationally competitive research will result in new knowledge and the substantiation of Australian research in the nuclear structure area, as well as adding to our role in international scientific collaborations. The research is an important component of the local expertise in nuclear science established using Australian facilities which provide the major training ground for basic research, a variety of applications and which also provide a source of strategically important expertise.
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Pure and applied nuclear structure research with radioactive ion beams at Californium Rare Ion Breeder Upgrade (CARIBU). The structure of exotic neutron-rich nuclei will be investigated at the Californium Rare Ion Breeder Upgrade (CARIBU) radioactive ion beam facility using new and novel detector systems. The results will enhance our fundamental understanding of the atomic nucleus and stellar nucleosynthesis as well as provide important data for the development of next generation nuclear reactor ....Pure and applied nuclear structure research with radioactive ion beams at Californium Rare Ion Breeder Upgrade (CARIBU). The structure of exotic neutron-rich nuclei will be investigated at the Californium Rare Ion Breeder Upgrade (CARIBU) radioactive ion beam facility using new and novel detector systems. The results will enhance our fundamental understanding of the atomic nucleus and stellar nucleosynthesis as well as provide important data for the development of next generation nuclear reactors.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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