Precision low energy experiments to search for new physics. This project aims to give experimental answers to long existing theoretical questions about the origins and nature of dark matter. Dark matter is a fundamental component of the universe, yet the nature of its composition is still unknown. There is growing evidence that dark matter is comprised of low mass and weakly interacting particles. By developing ultra-precise measurement tools and new techniques, this project aims to perform a st ....Precision low energy experiments to search for new physics. This project aims to give experimental answers to long existing theoretical questions about the origins and nature of dark matter. Dark matter is a fundamental component of the universe, yet the nature of its composition is still unknown. There is growing evidence that dark matter is comprised of low mass and weakly interacting particles. By developing ultra-precise measurement tools and new techniques, this project aims to perform a stringent and comprehensive new laboratory search for ultra-light dark matter particles, over likely mass ranges not yet searched. The knowledge gained will provide economic benefits through commercialisation and stimulation of new research and development, and to defence through applications in radar, communications and sensing.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100073
Funder
Australian Research Council
Funding Amount
$174,627.00
Summary
Australian Contribution to CERN Large Hadron Collider Experiment Upgrade. Australian contribution to CERN large hadron collider experiment upgrade: The discovery of the Higgs Boson with the ATLAS experiment at the CERN laboratory's large hadron collider, has been a highlight for Australian science. Scientists will build upon the foundation of the Higgs discovery to further probe the nature of matter at the finest scales and highest energies. Detailed measurements of the Higgs characteristics wil ....Australian Contribution to CERN Large Hadron Collider Experiment Upgrade. Australian contribution to CERN large hadron collider experiment upgrade: The discovery of the Higgs Boson with the ATLAS experiment at the CERN laboratory's large hadron collider, has been a highlight for Australian science. Scientists will build upon the foundation of the Higgs discovery to further probe the nature of matter at the finest scales and highest energies. Detailed measurements of the Higgs characteristics will determine if it is as predicted by the Standard Model or whether it admits a variation, signalling new physics. The upgrade in this project will provide for such detailed measurements. It will also allow sensitive probes of new physics, searching for new particles or unexpected interactions.Read moreRead less
New generation nanostructured coatings with combined control of spectral and angular emissivity. The aim of this project is to generate a complete scientific understanding of a new generation of hybrid, tri-layered, optically-selective coatings. The new design paradigm combines the very different attributes of smooth and nanostructured layers so that superior and simultaneous control of both spectral and angular properties of light can be achieved. Existing theory will be extended so that quanti ....New generation nanostructured coatings with combined control of spectral and angular emissivity. The aim of this project is to generate a complete scientific understanding of a new generation of hybrid, tri-layered, optically-selective coatings. The new design paradigm combines the very different attributes of smooth and nanostructured layers so that superior and simultaneous control of both spectral and angular properties of light can be achieved. Existing theory will be extended so that quantitative analyses of these new systems and other hybrids become possible and new and improved fabrication techniques will be developed. The work will unlock new technological possibilities for coating performance and application and is likely to be associated with significant improvements in energy conservation and generation. Read moreRead less
Quantum enhancement of gravitational wave astronomy. The project aims to design, build and test a long wavelength ‘squeezed vacuum’ source reducing quantum noise by more than a factor of 10 across the audio frequency band with long term stability and reliability. This quantum technology is one of three key areas of improvement planned for the gravitational wave detector, LIGO Voyager. The project will enhance the sensitivity and the reach of gravitational wave astronomy and cosmology, and improv ....Quantum enhancement of gravitational wave astronomy. The project aims to design, build and test a long wavelength ‘squeezed vacuum’ source reducing quantum noise by more than a factor of 10 across the audio frequency band with long term stability and reliability. This quantum technology is one of three key areas of improvement planned for the gravitational wave detector, LIGO Voyager. The project will enhance the sensitivity and the reach of gravitational wave astronomy and cosmology, and improve the fidelity and reach of gravitational wave observations. Technologies developed may find application in other areas of precision measurements and gravitational wave observations .Read moreRead less
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.
Leading a coordinated international approach to understand the zeptosecond physics of superheavy element formation. Unique Australian experimental developments and concepts, to track the zeptosecond dynamics of fusion forming superheavy elements, have revealed unexpectedly strong quantum effects. The impact of these insights is attracting world-leaders in this vigorous field to collaborate with us. Leading an ambitious coordinated program of experiments in Australia and at big international faci ....Leading a coordinated international approach to understand the zeptosecond physics of superheavy element formation. Unique Australian experimental developments and concepts, to track the zeptosecond dynamics of fusion forming superheavy elements, have revealed unexpectedly strong quantum effects. The impact of these insights is attracting world-leaders in this vigorous field to collaborate with us. Leading an ambitious coordinated program of experiments in Australia and at big international facilities, and driving theoretical developments, this project will pin down the dynamics of heavy element formation. This will be a high-profile outcome from recent investment in Australian accelerators. Mapping out future opportunities at worldwide billion dollar accelerator developments will secure a strong Australian engagement and benefit from these massive investments.Read moreRead less
From coherent to dissipative dynamics in complex quantum systems: opening a new window through nuclear fusion. The new ideas and precision measurement technologies in the project will enhance the reputation of Australian research in the fundamental subjects of quantum tunnelling and nuclear fusion. The cutting-edge work, and its international linkages, provides outstanding training in quantum and nuclear science of national and international significance.
Imaging light elements, dopants and vacancies. This project will pioneer techniques for seeing light atoms, such as oxygen in superconductors and lithium in lithium battery materials. Coming to understand the function of light elements in advanced materials is vital as such materials play a pivotal role in meeting the pressing challenges that beset us in energy management.
Discovery Early Career Researcher Award - Grant ID: DE120101504
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Nano-resolution hard x-ray diffraction imaging with conventional laboratory sources. The project will combine advanced optics and algorithms for diffraction imaging to develop a desktop hard x-ray microscope. The system will display ultra-high resolution and will be highly complementary to electronic and optical microscopies for diverse applications in materials engineering, nanofluidics and cell biology.
Creating superheavy elements and isotopes. This project aims to measure properties, probabilities and timescales of competing quasifission processes, by combining Australian accelerator and detector capabilities with exotic radioactive targets. In 2015, nuclear fusion created superheavy elements with atomic numbers 113 to 118. The race is now on to create elements 119 and 120, as their production and properties should pin down the location of the predicted superheavy Island of Stability, but 3-f ....Creating superheavy elements and isotopes. This project aims to measure properties, probabilities and timescales of competing quasifission processes, by combining Australian accelerator and detector capabilities with exotic radioactive targets. In 2015, nuclear fusion created superheavy elements with atomic numbers 113 to 118. The race is now on to create elements 119 and 120, as their production and properties should pin down the location of the predicted superheavy Island of Stability, but 3-fragment quasifission is a major impediment to their formation. This project will evaluate quassification processes on the nuclear reactions proposed to form new superheavy elements and is expected to identify the best reactions for their discovery. The synthesis of new elements tests quantum physics, relativistic chemistry and element creation in the cosmos, and offers high profile returns on investments.Read moreRead less