Dynamic model and mechanical sensorless controller for a novel concentrated-winding interior permanent magnet machine for electric vehicles. The fractional-slot, concentrated-wound (FSCW) interior permanent magnet (IPM) machine offers very high power density, efficiency and constant-power speed range which are properties sought after for electric vehicles. Accurate mathematical models are essential for high performance control of the FSCW machine. This project seeks to develop these models, as w ....Dynamic model and mechanical sensorless controller for a novel concentrated-winding interior permanent magnet machine for electric vehicles. The fractional-slot, concentrated-wound (FSCW) interior permanent magnet (IPM) machine offers very high power density, efficiency and constant-power speed range which are properties sought after for electric vehicles. Accurate mathematical models are essential for high performance control of the FSCW machine. This project seeks to develop these models, as well as sensorless controllers for the FSCW IPM machine.Read moreRead less
High-speed interior permanent magnet synchronous machines. This project aims to develop a permanent magnet machine for high speed operation (more than 50,000 rpm). A high-speed interior permanent magnet machine will solve some of the complex constructional and sensor-less control issues related to high-speed drive systems. This project will develop permanent magnet machines with simple constructional features, reduced use of costly rare earth materials, inherent sensor-less control capability an ....High-speed interior permanent magnet synchronous machines. This project aims to develop a permanent magnet machine for high speed operation (more than 50,000 rpm). A high-speed interior permanent magnet machine will solve some of the complex constructional and sensor-less control issues related to high-speed drive systems. This project will develop permanent magnet machines with simple constructional features, reduced use of costly rare earth materials, inherent sensor-less control capability and flux-weakening. These machines are expected to be used in many global growth sectors including aerospace, automotive, manufacturing, energy generation and storage.Read moreRead less
Developing a complete understanding of nuclear fission. This project aims to develop a reliable predictive model of nuclear fission. Nuclear fission is an important process in fundamental physics and technologies spanning energy, medicine and materials science. It was recently found that fission still holds many secrets, since existing models fail to describe new fission measurements for nuclei lighter than the well-known uranium region. This project plans to exploit world-leading Australian res ....Developing a complete understanding of nuclear fission. This project aims to develop a reliable predictive model of nuclear fission. Nuclear fission is an important process in fundamental physics and technologies spanning energy, medicine and materials science. It was recently found that fission still holds many secrets, since existing models fail to describe new fission measurements for nuclei lighter than the well-known uranium region. This project plans to exploit world-leading Australian research equipment to map out unknown fission characteristics in large regions of the nuclear chart, providing a complete microscopic understanding of nuclear fission. This is designed to lead to the first predictive model applicable to the entire nuclear chart, including nuclei of astrophysical importance.Read moreRead less
Multi-region relaxation dynamics in fusion and stellar plasmas. This project aims to apply a static plasma modelling approach to linear modes of vibration and nonlinear explosive events in toroidally confined fusion plasma experiments and stellar atmospheres. The long-term survival of advanced civilisation depends on the development of reliable and ecologically sustainable energy sources. One of the most promising approaches for baseload electrical power is magnetic confinement fusion: harnessin ....Multi-region relaxation dynamics in fusion and stellar plasmas. This project aims to apply a static plasma modelling approach to linear modes of vibration and nonlinear explosive events in toroidally confined fusion plasma experiments and stellar atmospheres. The long-term survival of advanced civilisation depends on the development of reliable and ecologically sustainable energy sources. One of the most promising approaches for baseload electrical power is magnetic confinement fusion: harnessing, in a magnetic field, the nuclear reactions that power stars. This project will develop powerful new ways of modelling strong plasma instabilities in magnetised plasmas. Learning how to avoid these would remove a key barrier to fusion power.Read moreRead less
Modelling and distributed control of large infrastructure networks. The main outcome of this project will be the capability to study systematically basic questions on the operation of large infrastructure systems. Methodologies for control of larger systems and security issues will be developed. Application of the techniques to several applications areas will include power grids and traffic networks.
Anisotropy and flow in fast-particle dominated and burning tokamak plasmas: stability of ITER and the coming demonstration fusion power plant. This project will identify how beam injected and fusion born alphas affect the magnetic ?eld and excite wave modes in spherical tokamaks, where these particles have the most impact. Understanding these effects is critical to long pulse operation of high performance tokamaks with burning plasmas. In the UK spherical tokamak MAST for instance, fast ion driv ....Anisotropy and flow in fast-particle dominated and burning tokamak plasmas: stability of ITER and the coming demonstration fusion power plant. This project will identify how beam injected and fusion born alphas affect the magnetic ?eld and excite wave modes in spherical tokamaks, where these particles have the most impact. Understanding these effects is critical to long pulse operation of high performance tokamaks with burning plasmas. In the UK spherical tokamak MAST for instance, fast ion driven bursty “chirping modes” and “?shbone” modes evolve into "long-lived" modes damaging plasma performance. This project will resolve the physics of the seed fast ion driven mode, its linear threshold and fully nonlinear evolution. Wider outcomes include scoping the impact of beams and alphas in next step burning plasma experiments, such as a nuclear facility for materials development, ITER, and a fusion power plant.Read moreRead less
Emergence and control of self-organisation in fusion plasmas: through the International Thermonuclear Experimental Reactor (ITER) and beyond. Fusion is a carbon free technology, which promises millions of years of base-load power. The promise has led to massive support for the proof-of-principle experiment, ITER. A challenge facing ITER is minimising edge instabilities, which can destroy the plasma facing wall. The project will explore if a new model can describe and control these instabilities.
Building Schrodinger's cat: large-scale entanglement of trapped ions. Where does the microscopic quantum world leave off and the normal world begin? The project will expand the boundaries of the quantum realm by building the largest quantum objects ever assembled and put them to work in computing and cryptography. These quantum devices will help Australia lead the race for future information technologies.
Time-space resolved photoelectron emission to control molecular processes. This project aims to resolve simultaneously the timing and space localisation of photoelectron emission from atoms and molecules as a means for targeted breaking of molecular bonds. Existing techniques determine the timing and spatial characteristics of photoemission independently. The simultaneous time-space resolution will allow for the precise manipulation of photoelectrons by a sequence of phase-stabilised laser pulse ....Time-space resolved photoelectron emission to control molecular processes. This project aims to resolve simultaneously the timing and space localisation of photoelectron emission from atoms and molecules as a means for targeted breaking of molecular bonds. Existing techniques determine the timing and spatial characteristics of photoemission independently. The simultaneous time-space resolution will allow for the precise manipulation of photoelectrons by a sequence of phase-stabilised laser pulses, a technique known as coherent control. The benefit of this project will be the coherently controlled breaking of molecular bonds in oxide, carbonyl and hydrocarbon molecules. The outcome will be a significant step forward in driving complex photochemical reactions in industry.Read moreRead less
Enhancing the science reach of second generation interferometric gravitational wave detectors through innovative mirror design and control. Predicted by Einstein, gravitational waves promise to unlock the secrets of the universe just as seismic measurements unlocked the secrets of the Earth's interior. Scientists are on the brink of detecting these waves. This research aids that effort by developing Australian technologies which allow specific gravitational wave sources to be targeted.