Physics of Self-Organization: From Space Plasmas to Brain Dynamics. Nature displays intricate, self-organized structures and behaviors that often emerge from simple underlying rules. This project will explore and unify fundamental regimes of self-organization, and apply them to explain phenomena in space, plasma, and wave physics, including making key inputs to the international STEREO space mission. In a core initiative, sophisticated tools from these fields will be transfered and adapted to a ....Physics of Self-Organization: From Space Plasmas to Brain Dynamics. Nature displays intricate, self-organized structures and behaviors that often emerge from simple underlying rules. This project will explore and unify fundamental regimes of self-organization, and apply them to explain phenomena in space, plasma, and wave physics, including making key inputs to the international STEREO space mission. In a core initiative, sophisticated tools from these fields will be transfered and adapted to analyze self-organized brain dynamics, leading to the first self-consistent "working brain" model. The results of this innovation will be used to develop new imaging technologies, to probe brain function via the new windows they open, and to exploit them commercially.Read moreRead less
Superfluid helium nanodroplet spectroscopy. Molecules trapped in a helium nanodroplet find themselves in an ultracold liquid environment from which they cannot escape. As such, the molecules are forced to interact and this is studied at a resolution that is unrivaled in condensed phase spectroscopy. This technique will be used to create new materials and study the dynamics behind a large range of chemical processes. The results are expected to lead to a greater understanding of condensed phase c ....Superfluid helium nanodroplet spectroscopy. Molecules trapped in a helium nanodroplet find themselves in an ultracold liquid environment from which they cannot escape. As such, the molecules are forced to interact and this is studied at a resolution that is unrivaled in condensed phase spectroscopy. This technique will be used to create new materials and study the dynamics behind a large range of chemical processes. The results are expected to lead to a greater understanding of condensed phase chemistry and chemical reactions in general.Read moreRead less
Dynamics of Multiscale Complex Systems. Australia has built a strong position in the science and applications of multiscale phenomena, especially in interdisciplinary fields. The project will advance this position in plasma and biomedical physics by making new discoveries, developing new methods of analyzing such systems, and applying them to achieve practical outcomes. It will underpin Australia's participation in NASA's $600M STEREO mission, and will lead to improved methods and technologies ....Dynamics of Multiscale Complex Systems. Australia has built a strong position in the science and applications of multiscale phenomena, especially in interdisciplinary fields. The project will advance this position in plasma and biomedical physics by making new discoveries, developing new methods of analyzing such systems, and applying them to achieve practical outcomes. It will underpin Australia's participation in NASA's $600M STEREO mission, and will lead to improved methods and technologies for brain function analysis and imaging, which will be commercialized via industry partnerships. It will contribute to national research goals, especially in Breakthrough Science, Frontier Technologies, Smart Information Use, and Promoting Innovation.Read moreRead less
Quantitative Brain Dynamics. This proposal will benefit Australia through unique and fundamental contributions to understanding brain dynamics via the development of innovative approaches and technologies. It will contribute to the national priority goals of Breakthrough Science, Frontier Technologies, and Promoting an Innovation Culture and Economy. Science outcomes will include improved understanding and probing of brain self-organization, dynamics, and function, including unique contributio ....Quantitative Brain Dynamics. This proposal will benefit Australia through unique and fundamental contributions to understanding brain dynamics via the development of innovative approaches and technologies. It will contribute to the national priority goals of Breakthrough Science, Frontier Technologies, and Promoting an Innovation Culture and Economy. Science outcomes will include improved understanding and probing of brain self-organization, dynamics, and function, including unique contributions to understanding alertness and the foundations of vision. These outcomes will be applied to develop new technologies for brain imaging and monitoring.Read moreRead less
Quantitative dynamics of functional magnetic resonance imaging. By modeling and verifying the dynamics of brain activity and blood flow that underlie functional magnetic resonance imaging (fMRI), this project will yield improved scientific outcomes and imaging sensitivity. The new data analysis techniques and technologies that result will yield potentially patentable intellectual property, and will increase the standing of Australia in this rapidly developing field, including via links being bu ....Quantitative dynamics of functional magnetic resonance imaging. By modeling and verifying the dynamics of brain activity and blood flow that underlie functional magnetic resonance imaging (fMRI), this project will yield improved scientific outcomes and imaging sensitivity. The new data analysis techniques and technologies that result will yield potentially patentable intellectual property, and will increase the standing of Australia in this rapidly developing field, including via links being built to leading international workers. The National Research Priority Goals of Frontier Technologies, Breakthrough Science, Smart Information Use, and Promoting an Innovation Economy will thus be advanced.Read moreRead less
Parametric Brain Imaging via Modeling and Analysis of Electroencephalographic Signals. Parameters of brain function and physiology will be spatially imaged with high time resolution via their effects on electroencephalographic (EEG) signals, a form of imaging that is impossible with existing methods. This will be achieved by improving existing physiologically-based models of the generation of EEGs and developing analysis tools based on fitting of model predictions to multielectrode EEG data. T ....Parametric Brain Imaging via Modeling and Analysis of Electroencephalographic Signals. Parameters of brain function and physiology will be spatially imaged with high time resolution via their effects on electroencephalographic (EEG) signals, a form of imaging that is impossible with existing methods. This will be achieved by improving existing physiologically-based models of the generation of EEGs and developing analysis tools based on fitting of model predictions to multielectrode EEG data. The results will be used to probe spatiotemporal features of EEGs in normal subjects to explore the underlying fundamental mechanisms and to infer novel parameter variations of practical relevance.Read moreRead less
SILICON BASED PHOTONIC CRYSTALS FOR MONITORING BIOMOLECULAR INTERACTIONS. Two great goals of biomolecular science are to monitor biomolecular interactions in real time and with sufficient sensitivity to allow small amounts of biological material to be investigated. The achievement of these goals is limited by the methods of transducing these reactions. The aim of this multidisciplinary proposal is to overcome this limitation by developing photonic devices that exploit the unique properties of na ....SILICON BASED PHOTONIC CRYSTALS FOR MONITORING BIOMOLECULAR INTERACTIONS. Two great goals of biomolecular science are to monitor biomolecular interactions in real time and with sufficient sensitivity to allow small amounts of biological material to be investigated. The achievement of these goals is limited by the methods of transducing these reactions. The aim of this multidisciplinary proposal is to overcome this limitation by developing photonic devices that exploit the unique properties of nanoporous silicon. The hybridisation of DNA will be used as a model biorecognition reaction. Potential applications of these photonic devices are as highly sensitive affinity sensors and as tools for investigating the kinetics of biomolecular interactions.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989390
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Versatile Scanning X-ray Microscopy Facility at the Australian Synchrotron. The challenges of the modern world means that the Australian community must continue to have access to state of the art research tools. An important component of international synchrotron sources is the very high resolution x-ray microscope. These microscopes are used to image samples of biological, material or environmental significance with extraordinary precision. This project will establish such a microscope at the A ....Versatile Scanning X-ray Microscopy Facility at the Australian Synchrotron. The challenges of the modern world means that the Australian community must continue to have access to state of the art research tools. An important component of international synchrotron sources is the very high resolution x-ray microscope. These microscopes are used to image samples of biological, material or environmental significance with extraordinary precision. This project will establish such a microscope at the Australian Synchrotron in Clayton, and nucleates an extensive nationwide collaboration that is devoted to the development of this and related techniques and their application to problems of national scientific, environmental and technological importance.Read moreRead less
Special Research Initiatives - Grant ID: SR0354716
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Energetically Open Systems Research Network Study. Conceptual frameworks arising in the physical sciences, such as non-equilibrium statistical mechanics and thermodynamics, synergetics, chaos and dynamical systems theory, are seminal in the emerging science of complexity. This study will lay the groundwork for a network to link Australian and overseas research on these fundamental concepts, and their application within the context of entropy-producing systems vital to the long-term sustainabilit ....Energetically Open Systems Research Network Study. Conceptual frameworks arising in the physical sciences, such as non-equilibrium statistical mechanics and thermodynamics, synergetics, chaos and dynamical systems theory, are seminal in the emerging science of complexity. This study will lay the groundwork for a network to link Australian and overseas research on these fundamental concepts, and their application within the context of entropy-producing systems vital to the long-term sustainability of the earth - oceans, atmosphere, biosphere, CO2-free energy production, space and solar environment. The network would facilitate the development of young investigators and be linked into wider complex systems networks such as the CSIRO Centre for Complex Systems Science.Read moreRead less
Special Research Initiatives - Grant ID: SR0354658
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
The Nanoparticle Network. Nanoscale materials are objects with one dimension less than about 20nm in size. Such exotic materials display unique, size-dependent properties (called "quantum size effects"). These materials will form the basis for many of the technological advances of the 21st Century. "The Nanoparticle Network" is a consortium dedicated to the exploration of different nanoscale materials and the origin of quantum size effects. The Network aims to enhance the uptake of all types of ....The Nanoparticle Network. Nanoscale materials are objects with one dimension less than about 20nm in size. Such exotic materials display unique, size-dependent properties (called "quantum size effects"). These materials will form the basis for many of the technological advances of the 21st Century. "The Nanoparticle Network" is a consortium dedicated to the exploration of different nanoscale materials and the origin of quantum size effects. The Network aims to enhance the uptake of all types of nanoparticle based technologies through an integrated network of scientists and engineers in conjunction with industry partners and government research institutions.
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