Towards a steady-state fusion reactor: understanding and controlling eruptive instabilities in tokamaks. The lifetime of future fusion reactors may be severely compromised by periodic releases of internal energy which can damage the reactor walls. In an international research effort that is based on unique Australian optical technologies, the project aims to resolve some of the key issues that should allow these instabilities to be suppressed.
Physics of a new low power electrothermal radiofrequency plasma thruster. Electric propulsion is the new wave of attitude control for spacecraft. Space engines must be small, lightweight and able to run unattended for over 20 years in a very harsh environment. The physics of a new electrothermal radiofrequency plasma thruster will be investigated. Neutral gas heating will be initially quantified by optical spectroscopy combined with computer generated simulated spectra. A space ready prototype w ....Physics of a new low power electrothermal radiofrequency plasma thruster. Electric propulsion is the new wave of attitude control for spacecraft. Space engines must be small, lightweight and able to run unattended for over 20 years in a very harsh environment. The physics of a new electrothermal radiofrequency plasma thruster will be investigated. Neutral gas heating will be initially quantified by optical spectroscopy combined with computer generated simulated spectra. A space ready prototype will be designed, manufactured and developed to carry out direct measurements of thrust and gas heating in our large space simulation vacuum facility.Read moreRead less
Studies of turbulence and coherent structures in quasi two-dimensional plasmas and fluids. One of the most celebrated but least understood complex systems in nature is turbulent flow. This cross-disciplinary project aims to contribute to basic scientific knowledge of a class of turbulent flows, known as quasi two-dimensional fluids, that typically exhibit self-organizing properties, stable sheared flow, and relatively weak dissipation. The significance lies in the proposed testing, by modelling ....Studies of turbulence and coherent structures in quasi two-dimensional plasmas and fluids. One of the most celebrated but least understood complex systems in nature is turbulent flow. This cross-disciplinary project aims to contribute to basic scientific knowledge of a class of turbulent flows, known as quasi two-dimensional fluids, that typically exhibit self-organizing properties, stable sheared flow, and relatively weak dissipation. The significance lies in the proposed testing, by modelling and simulation studies, of the well-grounded hypothesis that suppression of turbulence by sheared flow is a universal phenomenon in such fluids, and that it can be exploited to control transport of fluid constituents. Applications of this new knowledge will be developed.Read moreRead less
Positronic Atoms - A Search for Positron Bound States. An experimental verification of positron bound states will solve a long standing problem in positron physics. A clear understanding of positron binding and the underlying mechanisms will open a new era in low-energy positron-atom/molecular physics, leading the way for breakthrough sciences. For instance, a positron bound state should enhance the annihilation rate between the positron and target valence electron. Positron annihilation, to pro ....Positronic Atoms - A Search for Positron Bound States. An experimental verification of positron bound states will solve a long standing problem in positron physics. A clear understanding of positron binding and the underlying mechanisms will open a new era in low-energy positron-atom/molecular physics, leading the way for breakthrough sciences. For instance, a positron bound state should enhance the annihilation rate between the positron and target valence electron. Positron annihilation, to produce two gamma rays, is a key process in both materials research (e.g. as already heavily employed in defect detection) and bio-medical treatments (e.g. the Positron Emission Tomography, or PET).Read moreRead less
A Microscope for Molecular Reactions. We are proposing to combine new, state-of-the-art detector technology and innovative experimental techniques in the development of A Microscope for Molecular Reactions. This device will enable precise and highly efficient studies on the structure of molecules and their interactions with the physical world. It will be applied to a broad range of problems in contemporary atomic and molecular physics, and will lead to new insights into the dynamics of such re ....A Microscope for Molecular Reactions. We are proposing to combine new, state-of-the-art detector technology and innovative experimental techniques in the development of A Microscope for Molecular Reactions. This device will enable precise and highly efficient studies on the structure of molecules and their interactions with the physical world. It will be applied to a broad range of problems in contemporary atomic and molecular physics, and will lead to new insights into the dynamics of such reactions and their role in our everyday lives.Read moreRead less
Benchmark Studies of Positron Interactions with Helium. Australia has been at the forefront of experimental studies of electron-driven processes and theoretical descriptions of positron interactions. A new experimental program to study experimental low energy positron atomic physics provides a perfect synergy of these two areas of expertise. The field is a relatively new and emerging one and is focused around a number of new experimental approaches, such as those being developed at the Austral ....Benchmark Studies of Positron Interactions with Helium. Australia has been at the forefront of experimental studies of electron-driven processes and theoretical descriptions of positron interactions. A new experimental program to study experimental low energy positron atomic physics provides a perfect synergy of these two areas of expertise. The field is a relatively new and emerging one and is focused around a number of new experimental approaches, such as those being developed at the Australian National University. This set of experiments, on positron interactions with helium, will provide new experimental evidence to further our understanding of fundamental quantum processes and place Australia at the forefront of the field.Read moreRead less
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
Unravelling the neutron lifetime puzzle with lattice quantum chromodynamics. This project will perform supercomputer simulations to confront one of the outstanding puzzles of nuclear and particle physics, the neutron lifetime. New knowledge will be generated through the development of novel theoretical and numerical techniques to increase the precision of the leading theoretical inputs required to predict the neutron lifetime. The outcomes will provide crucial theoretical guidance into understan ....Unravelling the neutron lifetime puzzle with lattice quantum chromodynamics. This project will perform supercomputer simulations to confront one of the outstanding puzzles of nuclear and particle physics, the neutron lifetime. New knowledge will be generated through the development of novel theoretical and numerical techniques to increase the precision of the leading theoretical inputs required to predict the neutron lifetime. The outcomes will provide crucial theoretical guidance into understanding the neutron; helping to guide the next-generation neutron experiments, from particle physics to applications in advanced materials science. The results will have immediate benefit by resolving the neutron lifetime puzzle, while enabling Australian scientists to take a leadership role in this area of fundamental science.Read moreRead less
Imaging the spatial distribution of forces that bind quarks to a proton. This project will perform supercomputer simulations to resolve the distribution of forces acting on quarks inside the proton. New knowledge will be generated in the area of fundamental strong-interaction physics by developing innovative approaches to image novel features that have not been possible in the past. The outcomes will therefore open new research possibilities by expanding the capacity of the international communi ....Imaging the spatial distribution of forces that bind quarks to a proton. This project will perform supercomputer simulations to resolve the distribution of forces acting on quarks inside the proton. New knowledge will be generated in the area of fundamental strong-interaction physics by developing innovative approaches to image novel features that have not been possible in the past. The outcomes will therefore open new research possibilities by expanding the capacity of the international community to study strong interaction physics—including direct relevance to experimental research at the recently-upgraded Jefferson Lab in the US. In analogy to Rutherford's atomic model, the results will have benefit to future generations of humanity with a deeper understanding of the structure of matter.Read moreRead less
Nuclear vibrations under scrutiny in near-spherical and deformed nuclei. This Project aims to elucidate the nature of nuclear vibrations. Evidence is mounting that nuclear excitations long identified as vibrations cannot truly be so. This shakes the foundations of nuclear theory. Coulomb excitation and transfer reaction experiments are to be developed to probe the structure of these quantum states. Expected outcomes include clarification of their true nature and a deeper understanding of why nuc ....Nuclear vibrations under scrutiny in near-spherical and deformed nuclei. This Project aims to elucidate the nature of nuclear vibrations. Evidence is mounting that nuclear excitations long identified as vibrations cannot truly be so. This shakes the foundations of nuclear theory. Coulomb excitation and transfer reaction experiments are to be developed to probe the structure of these quantum states. Expected outcomes include clarification of their true nature and a deeper understanding of why nuclei differ from other many-body quantum systems that do vibrate. Anticipated benefits include enduring methodologies to facilitate international research engagement, and rigorous hands-on training in nuclear methods, to help meet Australia’s need for nuclear-qualified personnel in health, mining, industry and security.Read moreRead less