Real-time imaging of crystal strengthening mechanisms in metals. The strength limit of a metal is marked by rapid motion of crystalline defects. The associated speeds can locally approach that of sound. To probe the associated mechanisms clearly requires both spatial and temporal resolution. We propose to create a new bulk x-ray technique with an unprecedented combination of temporal and spatial resolution. We plan to exploit the technique to mediate a step change in modelling strength based on ....Real-time imaging of crystal strengthening mechanisms in metals. The strength limit of a metal is marked by rapid motion of crystalline defects. The associated speeds can locally approach that of sound. To probe the associated mechanisms clearly requires both spatial and temporal resolution. We propose to create a new bulk x-ray technique with an unprecedented combination of temporal and spatial resolution. We plan to exploit the technique to mediate a step change in modelling strength based on twinning. The formation of crystalline twins is known to dictate the strength of the light metal magnesium. A fuller understanding of the effect of twinning on strength in this metal will provide much needed confidence to implement it more widely in energy saving applications.Read moreRead less
X-ray Ghost Imaging and Tomography. This project aims to achieve safer, faster, and cheaper 3D X-ray imaging through a technique known as ghost imaging. X-ray imaging provides valuable information about internal structures, however, X-rays are carcinogenic and exposure (or dose) should be limited. Ghost imaging is an unconventional technique developed with visible light that has many potential benefits over conventional imaging. This research group are world leaders in ghost imaging and expect t ....X-ray Ghost Imaging and Tomography. This project aims to achieve safer, faster, and cheaper 3D X-ray imaging through a technique known as ghost imaging. X-ray imaging provides valuable information about internal structures, however, X-rays are carcinogenic and exposure (or dose) should be limited. Ghost imaging is an unconventional technique developed with visible light that has many potential benefits over conventional imaging. This research group are world leaders in ghost imaging and expect to develop software and hardware techniques to realise its potential and extend it to ghost tomography. The focus of this project is on reducing cancer risk in medical imaging, and allowing real-time quality control for 3D printing in safety-critical industries such as aerospace.Read moreRead less
Sulfur isotope fractionations in Earth evolution. Sulfur isotopes provide a unique window into the major events in Earth's history. Techniques have been developed for measuring all four sulfur isotopes, including the low abundance sulfur-36 (0.02 per cent) to 0.2 per mil, in situ for sulfides. This project will make innovative technological developments to the counting system to extend this capability to the lower count rates obtained from sulfates. This will open windows for research on proces ....Sulfur isotope fractionations in Earth evolution. Sulfur isotopes provide a unique window into the major events in Earth's history. Techniques have been developed for measuring all four sulfur isotopes, including the low abundance sulfur-36 (0.02 per cent) to 0.2 per mil, in situ for sulfides. This project will make innovative technological developments to the counting system to extend this capability to the lower count rates obtained from sulfates. This will open windows for research on processes occurring in the early solar system, atmospheric and hydrologic conditions in the Archean, ore-forming processes, and evolution of life on Earth. Read moreRead less
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.
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
Mapping the microscopic pathway to dissipation in quantum nuclear collisions. Nuclear reactions power the universe and produce all the chemical elements, whose abundances are a sensitive probe of energetic cosmic events. Our new concepts and experiments will probe the boundaries of the quantum world, guide applications of international radioactive isotope accelerators and address the problem of lithium abundance in the cosmos.
Quantum enhancement of long baseline gravitational wave detectors. This project will design and construct a quantum optical system which when used in future long baseline gravitational wave detectors will enhance sensitivity across their detection frequency band, from 10 Hz to 10 kHz. This project will use this system on small scale optical sensors to prove the concept. In so doing, it will use squeezing to reduce quantum radiation pressure noise for the first time. This system will then be read ....Quantum enhancement of long baseline gravitational wave detectors. This project will design and construct a quantum optical system which when used in future long baseline gravitational wave detectors will enhance sensitivity across their detection frequency band, from 10 Hz to 10 kHz. This project will use this system on small scale optical sensors to prove the concept. In so doing, it will use squeezing to reduce quantum radiation pressure noise for the first time. This system will then be ready for deployment on an early upgrade of Advanced LIGO increasing the science output of this detector, turning gravitational wave detection into gravitational wave astronomy.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
Ultrasensitive single atom-counting for astrophysics and nuclear technology. This project aims to study nuclear reactions identified as highest priority by United States and European working groups. This project addresses a wide range of applications that are critical to society, the generation of energy (nuclear fusion, fission, advanced nuclear systems), medical applications, national security and environmental applications. It addresses the fundamental question of where all the elements origi ....Ultrasensitive single atom-counting for astrophysics and nuclear technology. This project aims to study nuclear reactions identified as highest priority by United States and European working groups. This project addresses a wide range of applications that are critical to society, the generation of energy (nuclear fusion, fission, advanced nuclear systems), medical applications, national security and environmental applications. It addresses the fundamental question of where all the elements originate and will benefit the general community with qualified research in nuclear technology, non-proliferation, nuclear safeguards and through accelerator-based research relevant, for example, for hadron therapy.Read moreRead less
Developing new techniques for mapping soil loss and movement in Australia. Soil erosion is a major problem for Australia. This project will develop and test a new and sensitive method to quantify soil loss and measure soil erosion and transport, using cutting-edge technologies conceived and developed in Australia.