High resolution ultrafast imaging with cold electrons. This project will develop atomic-scale imaging that is able to bypass the resolution limitations of modern electron microscopes. The project will investigate the physical processes underlying a new imaging source based on extracting cold electrons from laser-cooled atoms. Ultrashort pulses of cold electrons will enable time-lapse imaging of fundamental processes at the nano-scale, with applications in fundamental biosciences and materials sc ....High resolution ultrafast imaging with cold electrons. This project will develop atomic-scale imaging that is able to bypass the resolution limitations of modern electron microscopes. The project will investigate the physical processes underlying a new imaging source based on extracting cold electrons from laser-cooled atoms. Ultrashort pulses of cold electrons will enable time-lapse imaging of fundamental processes at the nano-scale, with applications in fundamental biosciences and materials science.Read moreRead less
Bright x-ray beams from laser-driven microplasmas. This project aims to develop a new generation of bright, laser-like x-ray sources for laboratory use. X-ray sources underpin key diagnostic techniques in materials science, advancing applications from structural engineering through to ore processing and energy storage. However, the limited brightness of present-day laboratory x-ray sources restricts the utility and range of these diagnostic techniques. This research intends to use intense lasers ....Bright x-ray beams from laser-driven microplasmas. This project aims to develop a new generation of bright, laser-like x-ray sources for laboratory use. X-ray sources underpin key diagnostic techniques in materials science, advancing applications from structural engineering through to ore processing and energy storage. However, the limited brightness of present-day laboratory x-ray sources restricts the utility and range of these diagnostic techniques. This research intends to use intense lasers to create microscopic plasmas and drive high harmonic generation. The high harmonic generation process is already used to create laser-like ultraviolet light. By optimising the characteristics of the plasma medium, the project aims to extend bright high harmonic generation to the x-ray regime.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.
On the Fast Track to the Frontier of High-Energy Physics. This project aims to extend our reach in exploring fundamental physics by exploiting a novel fast pattern-recognition technique and extending its limit beyond the current capacity. The recent discovery of the Higgs boson confirmed the remaining element of the standard model of particle physics, yet many fundamental questions about the microscopic nature of the universe remain. The Large Hadron Collider upgrades provide an opportunity to m ....On the Fast Track to the Frontier of High-Energy Physics. This project aims to extend our reach in exploring fundamental physics by exploiting a novel fast pattern-recognition technique and extending its limit beyond the current capacity. The recent discovery of the Higgs boson confirmed the remaining element of the standard model of particle physics, yet many fundamental questions about the microscopic nature of the universe remain. The Large Hadron Collider upgrades provide an opportunity to measure the particle's properties and to discover new physics processes by enabling searches for new particles at the high-energy frontier. This project aims to exploit the unique datasets anticipated, develop key electronic components and new techniques that will expand the physics reach of the ATLAS experiment.Read moreRead less
Controlling spin coherence with rotation. This project aims to harness the ability to control the fundamental interactions which limit the precision of a diamond quantum sensor, enabling more sensitive magnetometry. Quantum sensors are unveiling new insights into nano-scale phenomena. Single atom defects in diamonds have been at the forefront of this revolution in nano-scale sensor technology. A unique capability, spinning diamond quantum sensors at up to 500,000 rpm, fast enough that quantum pr ....Controlling spin coherence with rotation. This project aims to harness the ability to control the fundamental interactions which limit the precision of a diamond quantum sensor, enabling more sensitive magnetometry. Quantum sensors are unveiling new insights into nano-scale phenomena. Single atom defects in diamonds have been at the forefront of this revolution in nano-scale sensor technology. A unique capability, spinning diamond quantum sensors at up to 500,000 rpm, fast enough that quantum properties of the defects are preserved during a cycle has been established. This project will address the long-standing problem of nano-scale solid-materials characterisation using rotationally-enhanced quantum magnetic resonance spectroscopy.Read moreRead less
Nanodiamond in glass: a new approach to nanosensing. This work will develop optical materials enriched with diamond nanoparticles. This will enable the magnetic field sensitivity of diamond nanoparticles to be combined with the capacity of micro/nanostructured optical fibres to enhance the interaction of light with matter. The outcome will be tools for probing biological processes on the nanoscale.
Seeing is believing: Microscopy-capable single-molecule bioelectronics. This project aims to create new biophysical tools for single-molecule sensing by advancing the state-of-the-art in nanoscale bioelectronic devices. The goal is to generate novel bioelectronic devices optimised for fabrication on microscope coverslip (170 micron glass) for compatibility with new low-cost platforms for advanced biological microscopy. Expected outcomes include the first organic electrochemical transistors inter ....Seeing is believing: Microscopy-capable single-molecule bioelectronics. This project aims to create new biophysical tools for single-molecule sensing by advancing the state-of-the-art in nanoscale bioelectronic devices. The goal is to generate novel bioelectronic devices optimised for fabrication on microscope coverslip (170 micron glass) for compatibility with new low-cost platforms for advanced biological microscopy. Expected outcomes include the first organic electrochemical transistors interfaced to constrained area lipid bilayers for studying membrane proteins at single-molecule level and nanoscale transistors for electrostatically detecting motile microtubules in in-vitro molecular motor assays for biocomputation. The intended benefit is innovation in capabilities and manufacturing of bioelectronics.Read moreRead less
Single spin molecular microscope. This project aims to create a new tool for imaging and analysing material at the atomic level. The tool is based on individual quantum coherent spins in diamond which can be manipulated and optically read. The project expects to generate knowledge in quantum metrology and an understanding of molecular dynamics at the nanoscale. The expected outcome is a new type of device capable of imaging complex physical systems at the level of their individual constituent co ....Single spin molecular microscope. This project aims to create a new tool for imaging and analysing material at the atomic level. The tool is based on individual quantum coherent spins in diamond which can be manipulated and optically read. The project expects to generate knowledge in quantum metrology and an understanding of molecular dynamics at the nanoscale. The expected outcome is a new type of device capable of imaging complex physical systems at the level of their individual constituent components. This has significant benefits in improving designer materials, energy production, information storage, and drug design.Read moreRead less