Antihydrogen formation. This project aims to advance fundamental understanding of collisions involving antimatter. The dominance of matter over antimatter in the Universe is one of the most intriguing questions of today’s science. Researchers at the European Organisation for Nuclear Research (CERN) are addressing this question by creating antihydrogen and studying its properties, including the gravitational behaviour. By trapping and cooling antihydrogen positive ions, ultra-cold antihydrogen at ....Antihydrogen formation. This project aims to advance fundamental understanding of collisions involving antimatter. The dominance of matter over antimatter in the Universe is one of the most intriguing questions of today’s science. Researchers at the European Organisation for Nuclear Research (CERN) are addressing this question by creating antihydrogen and studying its properties, including the gravitational behaviour. By trapping and cooling antihydrogen positive ions, ultra-cold antihydrogen atoms can be created and used in free fall experiments at CERN. The convergent close-coupling method and threshold theory will be used to provide the necessary theoretical guidance for the experimental antihydrogen positive ion formation via low-energy positronium-antiproton and positronium-antihydrogen collisions.Read moreRead less
Quantum collision physics. Collisions on the atomic scale occur all around us. The range of applications that benefit from a quantitative knowledge of such collisions is enormous, and includes lasers, lighting, plasma displays, fusion energy, atmospheric modelling, and the astrophysical sciences.
Discovery Early Career Researcher Award - Grant ID: DE160100098
Funder
Australian Research Council
Funding Amount
$403,536.00
Summary
Can positronium fragment complex molecules? This project aims to explore whether positronium, which is produced in the body during positron emission tomography (PET), can damage DNA. PET scans are used to locate cancer. Positrons produce positronium, a matter-antimatter bound state, in the body during a PET scan. It is known that electrons can damage DNA by forming a transient negative ion that fragments DNA building blocks and it is suggested that positronium could damage DNA in the same way. T ....Can positronium fragment complex molecules? This project aims to explore whether positronium, which is produced in the body during positron emission tomography (PET), can damage DNA. PET scans are used to locate cancer. Positrons produce positronium, a matter-antimatter bound state, in the body during a PET scan. It is known that electrons can damage DNA by forming a transient negative ion that fragments DNA building blocks and it is suggested that positronium could damage DNA in the same way. This work will explore fragmentation of DNA nucleobases by positronium impact. The results of this work may contribute to new models of PET use.Read moreRead less
Atto-second atomic dynamics. Recent progress in short laser pulse generation allows one to capture electron dynamics on the atomic time scale. The project will aim to combine these new experimental capabilities with detailed quantum mechanical calculations and a new physical approach, which will improve dramatically our ability to gain new knowledge about fundamental atomic processes.
Correlation Effects in Gas-Phase Positron Scattering. This project will apply new, state-of-the-art experimental positron technology in order to gain a deeper understanding of correlations in positron-atom and/or positron-molecule collision systems. The ambitious experimental program will investigate several of the major remaining 'big' questions in positron science. It is expected that the experimental evidence provided for processes such as threshold ionisation, positron bound states, and othe ....Correlation Effects in Gas-Phase Positron Scattering. This project will apply new, state-of-the-art experimental positron technology in order to gain a deeper understanding of correlations in positron-atom and/or positron-molecule collision systems. The ambitious experimental program will investigate several of the major remaining 'big' questions in positron science. It is expected that the experimental evidence provided for processes such as threshold ionisation, positron bound states, and other positronic complexes, will stimulate theoretical calculations in the field and lead to new insights into a number of quantum scattering processes.Read moreRead less
Life is swirl in flatland: two dimensional turbulence in a superfluid. The project will create two-dimensional turbulence in a superfluid gas of atoms in order to observe the predicted, but counter-intuitive, growth of ordered structure out of chaotic motion. The observation of such behaviour would support its mechanism as the explanation for phenomena such as giant eddies in ocean currents and the Great Red Spot of Jupiter.
Low-energy electron transport in soft-condensed biological matter. To obtain optimal accuracy and selectivity of ionising radiation based technologies requires an understanding and quantification of the underpinning fundamental physical processes. This project will focus on developing accurate theoretical models of low-energy electron transport in biological matter which account for new physical mechanisms.
Discovery Early Career Researcher Award - Grant ID: DE210101593
Funder
Australian Research Council
Funding Amount
$462,948.00
Summary
Developing new tools to search for dark matter. This project aims to propose and assist in the development of novel approaches, based on atomic, molecular and optical technologies, to detect dark matter in the laboratory, and thereby establish the identity and microscopic properties of dark matter. The origin and nature of dark matter remains one of the most important outstanding problems in contemporary science. The intended outcome of this project is that the use of our novel methods will enab ....Developing new tools to search for dark matter. This project aims to propose and assist in the development of novel approaches, based on atomic, molecular and optical technologies, to detect dark matter in the laboratory, and thereby establish the identity and microscopic properties of dark matter. The origin and nature of dark matter remains one of the most important outstanding problems in contemporary science. The intended outcome of this project is that the use of our novel methods will enable us to search for forms of dark matter that have remained largely unprobed to date. This in turn is expected to open up new opportunities in the global hunt for dark matter that should improve our chances of finally discovering the nature and properties of dark matter.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100399
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Are the laws of physics changing? New methods for detecting variations in the fundamental constants. This project will identify new methods whereby scientists are much more likely to discover whether the fundamental constants of nature, such as the speed of light, are changing with time. This will help answer deep questions about whether there are extra dimensions beyond our three, the nature of dark energy, and whether string theory is correct.
Electron scattering and transport for plasma-liquid interactions. The project aims to address the emerging technologies associated with the interaction of plasmas with liquids and biological matter, including plasma medicine. The project expects to generate new knowledge on the role of electron-induced processes through the development of complete and accurate sets of microscopic cross-sections for electrons with biomolecules within tissue. This microscopic data will inform new microscopic model ....Electron scattering and transport for plasma-liquid interactions. The project aims to address the emerging technologies associated with the interaction of plasmas with liquids and biological matter, including plasma medicine. The project expects to generate new knowledge on the role of electron-induced processes through the development of complete and accurate sets of microscopic cross-sections for electrons with biomolecules within tissue. This microscopic data will inform new microscopic models for non-equilibrium electron transport in liquids and biological matter, and its coupling to plasmas. The expected outcomes of this project include progress towards the optimisation of safety/efficacy of future generation plasma medicine devices through detailed understanding of plasma-biological tissue interactions.Read moreRead less