Quantum tunnelling of composite systems. This project aims to investigate profound physics problem of quantum tunnelling of composite systems such as atoms, molecules and atomic nuclei. Using new theoretical concepts and tools to describe low-energy fusion between atomic nuclei, this project is expected to generate new knowledge and improve understanding of nuclear reactions, the formation of elements in the cosmos, and underpin future nuclear technologies. The project aims to leverage Australia ....Quantum tunnelling of composite systems. This project aims to investigate profound physics problem of quantum tunnelling of composite systems such as atoms, molecules and atomic nuclei. Using new theoretical concepts and tools to describe low-energy fusion between atomic nuclei, this project is expected to generate new knowledge and improve understanding of nuclear reactions, the formation of elements in the cosmos, and underpin future nuclear technologies. The project aims to leverage Australian capacity in quantum and nuclear theory to produce the first predictive model of quantum tunnelling with a modern microscopic treatment of nuclear dynamics. It will provide new theoretical guidance to experimental programs with exotic beams and focussing on nucleosynthesis.Read moreRead less
Complex light and matter waves: merging nano-optics, quantum physics, and field theory. This project aims to address frontier problems at the confluence of nano-optics, plasmonics, electron microscopy, quantum weak measurements, and relativistic wave fields. Miniaturisation of devices, and ever-increasing amounts of processed information, lead to the increasing complexity of classical and quantum waves considered in fundamental science and exploited in applications. This project aims to develop ....Complex light and matter waves: merging nano-optics, quantum physics, and field theory. This project aims to address frontier problems at the confluence of nano-optics, plasmonics, electron microscopy, quantum weak measurements, and relativistic wave fields. Miniaturisation of devices, and ever-increasing amounts of processed information, lead to the increasing complexity of classical and quantum waves considered in fundamental science and exploited in applications. This project aims to develop novel methods and concepts, and unveil intriguing phenomena in physics of wave systems with nontrivial structure and internal degrees of freedom. This will provide deep insight into properties of complex classical and quantum waves, and new avenues for fine control of diverse light, matter, and mixed light-matter systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100098
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
National Facility for Quantum Diamond. Quantum technology is set to play a significant role in the next generation of sensors, computers and communication systems. Diamond is a critical part of this technology revolution as it allows for room temperature quantum-based applications. This projects aims to establish a world leading facility to engineer quantum-grade diamond for precision sensing, secure communications and desktop quantum computing applications. Direct outcomes from the facility inc ....National Facility for Quantum Diamond. Quantum technology is set to play a significant role in the next generation of sensors, computers and communication systems. Diamond is a critical part of this technology revolution as it allows for room temperature quantum-based applications. This projects aims to establish a world leading facility to engineer quantum-grade diamond for precision sensing, secure communications and desktop quantum computing applications. Direct outcomes from the facility include: ultrasensitive magnetometers for magnetoencephalography, atomic microscopes for biomolecular imaging and novel sensing probes to interface with biology. The facility will seed the emerging diamond quantum industry in Australia and train the next generation of quantum engineers.Read moreRead less
Microscopic many-body quantum dynamics: new approaches for fundamental science and applications. A new approach to create and validate a fundamental microscopic quantum theory of interactions of composite systems, like molecules and nuclei, by exploiting ideal features of nuclear reactions such as fusion will be developed. This will have broad impact in interdisciplinary areas from astrophysics and molecular reactions to future nanotechnologies.
Reaching the superheavy elements: a quantitative understanding through integrating new reaction time measurements with theoretical models. The project will develop new experimental methods to give unique insights into the interplay of quantum effects in nuclear fusion reactions forming heavy elements. The results will guide theoretical model developments to enhance understanding, and predict optimal opportunities to form new elements and isotopes with future rare isotope accelerators.
Australian Laureate Fellowships - Grant ID: FL110100098
Funder
Australian Research Council
Funding Amount
$2,750,752.00
Summary
Frontiers of reaction dynamics for new generation accelerator science. Innovative concepts and new Australian capabilities will be combined to understand reactions of exotic isotopes. This will underpin applications of next generation international rare isotope accelerators to advance many areas of physics, medical science and future energy technologies. The project strengthens national capacity in a strategic area.
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
Quantum thermalisation: a new framework for nuclear collisions. This project aims to quantify and model the processes that lead to quantum thermalisation in nuclear collisions. Thermalisation is critical to the synthesis of new superheavy elements, production of medical isotopes, and creation of heavy elements in the cosmos. Yet quantum thermalisation in nuclear systems is not understood, causing models to be wrong by up to a factor of 100. This project will determine the routes to thermalisatio ....Quantum thermalisation: a new framework for nuclear collisions. This project aims to quantify and model the processes that lead to quantum thermalisation in nuclear collisions. Thermalisation is critical to the synthesis of new superheavy elements, production of medical isotopes, and creation of heavy elements in the cosmos. Yet quantum thermalisation in nuclear systems is not understood, causing models to be wrong by up to a factor of 100. This project will determine the routes to thermalisation in nuclear systems by combining the latest concepts in many body quantum physics with enhancements to Australia’s precision measurement capabilities. The project will enable new fundamental tests of quantum mechanics and benefit broader applications of nuclear collisions.Read moreRead less
Foundations of the nuclear force, nuclear structure and dynamics. This project aims to investigate a profound problem in physics: the structure and interactions of atomic nuclei in terms of their microscopic constituents. It is expected to generate new knowledge and improve our understanding of the structure and dynamics of nuclei, their formation in the cosmos, neutron star properties, and underpin future nuclear technologies. The project aims to leverage Australian capacity in nuclear theory t ....Foundations of the nuclear force, nuclear structure and dynamics. This project aims to investigate a profound problem in physics: the structure and interactions of atomic nuclei in terms of their microscopic constituents. It is expected to generate new knowledge and improve our understanding of the structure and dynamics of nuclei, their formation in the cosmos, neutron star properties, and underpin future nuclear technologies. The project aims to leverage Australian capacity in nuclear theory to produce the first predictive model with a modern realistic nuclear interaction. Significant benefits include an enhancement of research training capacity and new international links with the world's major laboratories. Read moreRead less
Noncommutative analysis and geometry in interaction with quantum physics. Quantum theory has produced many advances in our understanding of the physical world for the last hundred years while mathematical breakthroughs have been made through exploiting innovative ideas from quantum physics. This project continues in this highly successful framework and will lead to advances in geometry both classical and noncommutative.