The hearts of galaxies. The centres of galaxies harbour fascinating astrophysical objects, such as black holes one thousand million times more massive than our Sun. This project will measure the damage that they have caused, searching for binary black holes, and helping to determine the extent to which galaxies have collided.
Massive black holes in dense star clusters. This project will be investigating the metamorphosis of dense star clusters containing millions of stars into massive black holes at the centres of galaxies. The research will be undertaken using the world's largest optical telescopes and one of the nation's fastest supercomputers.
Australian Laureate Fellowships - Grant ID: FL120100030
Funder
Australian Research Council
Funding Amount
$2,779,572.00
Summary
Engineering materials for advances in nanomedicine. Nanomedicine is one of the fastest growing areas in nanotechnology. This project will develop next-generation particle systems with engineered properties that are expected to underpin advances in the delivery of therapeutics in the areas of cancer, vaccines, cardiovascular disease and neural health.
Nanoengineered Polymeric Materials for Environmental and Biological Applications. The development of advanced materials with nanoengineered properties promises to revolutionise future industries, including the energy and healthcare sectors. This research program will involve the design, synthesis and assembly of tailored polymers to prepare next-generation, engineered materials. The research will deliver advanced polymeric membranes, tissue engineering scaffolds and vaccine delivery systems. The ....Nanoengineered Polymeric Materials for Environmental and Biological Applications. The development of advanced materials with nanoengineered properties promises to revolutionise future industries, including the energy and healthcare sectors. This research program will involve the design, synthesis and assembly of tailored polymers to prepare next-generation, engineered materials. The research will deliver advanced polymeric membranes, tissue engineering scaffolds and vaccine delivery systems. These materials are expected to provide benefits for Australian citizens in the energy and health sectors and contribute to the development of a robust Australian nanotechnology industry. The projects will also provide opportunities for the development of outstanding young scientists and will foster multidisciplinary collaborations.Read moreRead less
Neural spike variability: unifying conflicting views of neural dynamics. The project aims to improve our understanding of neural dynamics. The brain represents and processes information by means of neural voltage spikes, which show great variability in their timing. Understanding the origin of such variable neural dynamics is a long-standing problem in neuroscience. The aim of this project is to develop a novel account of variable neural dynamics, unravelling their computational principles in th ....Neural spike variability: unifying conflicting views of neural dynamics. The project aims to improve our understanding of neural dynamics. The brain represents and processes information by means of neural voltage spikes, which show great variability in their timing. Understanding the origin of such variable neural dynamics is a long-standing problem in neuroscience. The aim of this project is to develop a novel account of variable neural dynamics, unravelling their computational principles in the brain, and unifying current leading but conflicting theories. The model developed in this project would be used to explain a range of empirical observations, and the principles unravelled would be applied to understand spike-timing based neural coding. The new knowledge gained in this project may have profound implications for designing brain-like computing devices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100040
Funder
Australian Research Council
Funding Amount
$1,375,000.00
Summary
An advanced electron microscope facility for nanomaterials, functional materials and minerals. An advanced electron microscope facility for nanomaterials, functional materials and minerals: Recent advances in electron microscopy provide instruments that can resolve at the atomic level and image both morphologically and chemically at these resolutions. These modern instruments are also less complex to operate therefore allowing many more researchers to access them directly. The High Resolution Sc ....An advanced electron microscope facility for nanomaterials, functional materials and minerals. An advanced electron microscope facility for nanomaterials, functional materials and minerals: Recent advances in electron microscopy provide instruments that can resolve at the atomic level and image both morphologically and chemically at these resolutions. These modern instruments are also less complex to operate therefore allowing many more researchers to access them directly. The High Resolution Scanning Transmission Electron Microscope will allow a complete, nano-scale characterisation of natural and synthetic materials in a broad range of scientific, engineering and industrial applications. The Field Emission Scanning Electron Microscope will provide nano-science users with a tool that can image many of the processes in the formation of these nanostructures and particles.Read moreRead less
Special Research Initiatives - Grant ID: SR120200004
Funder
Australian Research Council
Funding Amount
$30,000,000.00
Summary
Australian Synchrotron Access Program. The Australian Synchrotron epitomises scientific research excellence in Australian and New Zealand. Its impact spans nearly every research sector. This proposal brings together over 30 Australian universities working together to ensure that world-class peer-reviewed science continues to be performed at the Australian Synchrotron.
Mathematical modelling of the dynamics of multi-layered biological tissues. The project intends to develop a mathematical model of the basic mechanisms that determine the self-organisation of cells into complex tissues during the development of the embryo. Tissue function requires a non-trivial tissue architecture often composed of multiple cell layers which exhibit a remarkable capacity for renewal and defect correction. A cardinal part of embryonic development involves robust shaping of multi- ....Mathematical modelling of the dynamics of multi-layered biological tissues. The project intends to develop a mathematical model of the basic mechanisms that determine the self-organisation of cells into complex tissues during the development of the embryo. Tissue function requires a non-trivial tissue architecture often composed of multiple cell layers which exhibit a remarkable capacity for renewal and defect correction. A cardinal part of embryonic development involves robust shaping of multi-layered tissue morphologies. The project plans to use mathematical models to determine how complex, three-dimensional structures arise from adaptive multicellular biomechanical interactions. It plans to develop a novel computational modelling framework to represent and analyse such systems, which may be applicable to a wide range of problems where tissue mechanics is a key factor such as bone remodelling and wound healing.Read moreRead less
How motor proteins contract the cell cortex and form a cell division ring. This project aims to develop a detailed physical model for motor proteins and filaments and, based on it, derive a fluid-type mean-field mathematical model, which will facilitate numerical simulations and lead to testable predictions. This study will also provide detailed quantitative information on how these processes can be controlled by modifying concentration and properties of structural and motor proteins. This has p ....How motor proteins contract the cell cortex and form a cell division ring. This project aims to develop a detailed physical model for motor proteins and filaments and, based on it, derive a fluid-type mean-field mathematical model, which will facilitate numerical simulations and lead to testable predictions. This study will also provide detailed quantitative information on how these processes can be controlled by modifying concentration and properties of structural and motor proteins. This has potential applications in tumour therapy, developmental biology and in the bioengineering of nanomaterials.Read moreRead less
Dynamics of droplets and nanoparticles in turbulent flames. This project aims to study the dynamics of liquid fragments and the morphology of synthesised nanoparticles in atomising spray flames. Outcomes will include experimental databases and predictive models for atomising spray flames and nanoparticle inception, as well as a novel atomiser for flame spray pyrolysis. These will provide significant benefits to researchers and industry working on the optimisation of nanostructured material synth ....Dynamics of droplets and nanoparticles in turbulent flames. This project aims to study the dynamics of liquid fragments and the morphology of synthesised nanoparticles in atomising spray flames. Outcomes will include experimental databases and predictive models for atomising spray flames and nanoparticle inception, as well as a novel atomiser for flame spray pyrolysis. These will provide significant benefits to researchers and industry working on the optimisation of nanostructured material synthesis for smart sensors and catalysts, and the next generation efficient and low emission combustion engines.Read moreRead less