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.
Novel collision experiments with metastable neon atoms in an atom trap. The aim of this project is to investigate collisions involving atoms in long lived excited states (metastable states). The project will utilise a magneto-optical trap to investigate electron-atom collisions as well as interatomic collisions for ultra-cold atoms. The outcomes of such investigations extend scientific knowledge of these important processes as a well as provide data for testing fundamental scattering theories. T ....Novel collision experiments with metastable neon atoms in an atom trap. The aim of this project is to investigate collisions involving atoms in long lived excited states (metastable states). The project will utilise a magneto-optical trap to investigate electron-atom collisions as well as interatomic collisions for ultra-cold atoms. The outcomes of such investigations extend scientific knowledge of these important processes as a well as provide data for testing fundamental scattering theories. This scientific knowledge may lead to further technological advances such as more efficient light sources or a metastable-atom laser that could be used for the production of nano-scale electric circuits.Read moreRead less
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
Positron Nano-Dosimetry: Fundamental Measurements of Positron Interactions and their use in State-of-the-Art Modelling of Positron Transport. This proposal will provide unique experimental and theoretical information on how positrons, the electron antiparticles, interact with matter, in particular with biologically important molecules. This data will be used in a unique set of modelling approaches which will provide, for the first time, an insight into how positrons are transported through gases ....Positron Nano-Dosimetry: Fundamental Measurements of Positron Interactions and their use in State-of-the-Art Modelling of Positron Transport. This proposal will provide unique experimental and theoretical information on how positrons, the electron antiparticles, interact with matter, in particular with biologically important molecules. This data will be used in a unique set of modelling approaches which will provide, for the first time, an insight into how positrons are transported through gases, liquids and ultimately, soft matter. It will thus have important ramifications for diagnostic tools such as Positron Emission Tomography. The fundamental research will also shed light on one of the key 'mysteries' of life - why the biological building blocks of life possess a definite " handedness", or chirality.Read moreRead less
RadioGenes2: Modelling complex biomolecular interactions in radiated tumours: Towards understanding the genesis of therapeutic radioresistance. About 45% of bladder cancer patients require radiotherapy or surgery. Radiotherapy has a failure rate of ~50%. Surgery (bladder removal) diminishes quality of life considerably. Modelling complex gene interactions in radiated cancer cells will provide crucial knowledge on the molecular genesis of radiotherapy-resistance of tumours. Our findings will prov ....RadioGenes2: Modelling complex biomolecular interactions in radiated tumours: Towards understanding the genesis of therapeutic radioresistance. About 45% of bladder cancer patients require radiotherapy or surgery. Radiotherapy has a failure rate of ~50%. Surgery (bladder removal) diminishes quality of life considerably. Modelling complex gene interactions in radiated cancer cells will provide crucial knowledge on the molecular genesis of radiotherapy-resistance of tumours. Our findings will provide: (i) an accurate mathematical/computational model for diagnosing radiosensitivity; (ii) further insights to be applied in the pharmaceutical sector such as the discovery of novel molecular targets that have the potential to increase radiotherapy success ratios; (iii) a holistic modelling technique applicable to a larger diversity of tumours.Read moreRead less
A Photonic Interconnect for Trapped Ion Quantum Computing. Computer networks are the foundation of our digital economy. Quantum computing offer revolutionary solutions to current limitations by taking advantage of quantum physics. Methods for factoring large numbers or searching unordered databases run with significantly fewer operations on quantum computers. Quantum encryption offers completely secure communication. There have been small-scale demonstrations of these technologies, and clear roa ....A Photonic Interconnect for Trapped Ion Quantum Computing. Computer networks are the foundation of our digital economy. Quantum computing offer revolutionary solutions to current limitations by taking advantage of quantum physics. Methods for factoring large numbers or searching unordered databases run with significantly fewer operations on quantum computers. Quantum encryption offers completely secure communication. There have been small-scale demonstrations of these technologies, and clear roadmaps exist for large-scale implementations. We will advance the state of the art by interconnecting light based quantum communication and trapped ion quantum computing together with phase Fresnel lenses, a micro-fabricated optic similar to a computer generated holographic plate.Read moreRead less
Correction of the Effects of Gradient Field Nonlinearity in Magnetic Resonance Imaging - A Complete 3-Dimensional Approach. The outcomes of this research will have direct benefits to various areas of diagnostic and interventional medicine especially in neurological diseases such as Alzheimer's disease, stroke, multiple sclerosis or brain tumors. The techniques developed in this project will in general enable MRI to provide a higher quality service to the community.
Attosecond physics with ultra cold metastable neon. This research will generate new knowledge about how atoms behave when they are placed in strong optical fields. One of the phenomena which can be observed in these systems is the production of extreme ultraviolet radiation. This radiation has potential applications in areas as diverse as precision spectroscopy and structural biology. The research will use the recently ARC funded, state-of-the-art short pulse laser facility, ultra-cold atom trap ....Attosecond physics with ultra cold metastable neon. This research will generate new knowledge about how atoms behave when they are placed in strong optical fields. One of the phenomena which can be observed in these systems is the production of extreme ultraviolet radiation. This radiation has potential applications in areas as diverse as precision spectroscopy and structural biology. The research will use the recently ARC funded, state-of-the-art short pulse laser facility, ultra-cold atom trap technology and will provide excellent research training opportunities for higher degree students. The outcomes of the research project will enable Australian researchers to make significant contributions to the exciting field of attosecond science which is still in its infancy.
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Role of senataxin protein in meiotic recombination and sex chromosome inactivation. Senataxin is a protein defective in the human genetic disorder ataxia oculomotor apraxia type 2. This project is designed to carry out mechanistic studies on the protein to establish its normal role in the cell.
Fundamental tests of Quantum Mechanics with the Atom Laser. This is high profile scientific research that is important to Australia's standing in the world scientific community. Atom optics was singled out as a key area of Australian science through the formation of the ARC Centre for Quantum Atom Optics in 2003, and is in the Breakthrough Science category of the Frontier Technologies priority funding area. The experimental schemes developed in this proposal contribute to the already strong expe ....Fundamental tests of Quantum Mechanics with the Atom Laser. This is high profile scientific research that is important to Australia's standing in the world scientific community. Atom optics was singled out as a key area of Australian science through the formation of the ARC Centre for Quantum Atom Optics in 2003, and is in the Breakthrough Science category of the Frontier Technologies priority funding area. The experimental schemes developed in this proposal contribute to the already strong experimental atom optics research in Australia. In order to remain at the forefront of fundamental physics research, Australia must maintain a world-class research effort in this area. Read moreRead less