Room-temperature quantum microscopy for advanced nanoscale imaging. Original, inspired and most often cross-disciplinary efforts are the only way to solve some of nature's most obscure mysteries. Successful development of high-resolution quantum microscopy will lead to a range of benefits for the community and the nation; from graduate student training in cutting edge technology, building links between academic, industry and government groups to providing new insights and approaches into diseas ....Room-temperature quantum microscopy for advanced nanoscale imaging. Original, inspired and most often cross-disciplinary efforts are the only way to solve some of nature's most obscure mysteries. Successful development of high-resolution quantum microscopy will lead to a range of benefits for the community and the nation; from graduate student training in cutting edge technology, building links between academic, industry and government groups to providing new insights and approaches into disease identification and therapy. This project aims to demonstrate a world-first in imaging sensitivity, and success will directly enhance Australia's global reputation as a leader in innovation and collaboration. Read moreRead less
Venturing into the Cluster Desert. Fundamental questions that ask about the nature and the fate of the Universe are of interest not only to astronomers, but also to the general public. In particular, the realisation that the Universe is dominated by dark energy has sparked wide public interest. We still know very little about dark energy. Is it Einstein's famous cosmological constant or something more exotic, such as a new particle or even new physics? This proposal aims to build a sample of ver ....Venturing into the Cluster Desert. Fundamental questions that ask about the nature and the fate of the Universe are of interest not only to astronomers, but also to the general public. In particular, the realisation that the Universe is dominated by dark energy has sparked wide public interest. We still know very little about dark energy. Is it Einstein's famous cosmological constant or something more exotic, such as a new particle or even new physics? This proposal aims to build a sample of very distant galaxy clusters that can then be used to search for a very special type of supernova - the Type Ia Supernova, which can be used as a tool to learn about the properties of dark energy. Read moreRead less
Visualising chaperones disentangle and refold proteins - one molecule at a time. Chaperones are enzymes that maintain the proper function of proteins in the cell. This research aims to visualise, at the single molecule level, how chaperones facilitate the folding of individual proteins and how they can disentangle proteins that have aggregated as a result of cell stress.
Unveiling the Galaxy: Dense Gas and Star Formation in the Milky Way. This project aims to address one of the most fundamental problems in astrophysics - understanding how high-mass stars form - by utilising a new, innovative, purpose-designed astronomical survey. This project will generate new knowledge about the star formation process by interfacing theoretical predictions with novel observations, aided by the most accurate distances yet derived. Expected outcomes include a comprehensive unders ....Unveiling the Galaxy: Dense Gas and Star Formation in the Milky Way. This project aims to address one of the most fundamental problems in astrophysics - understanding how high-mass stars form - by utilising a new, innovative, purpose-designed astronomical survey. This project will generate new knowledge about the star formation process by interfacing theoretical predictions with novel observations, aided by the most accurate distances yet derived. Expected outcomes include a comprehensive understanding of star formation, and an unparalleled map of the dense gas structure of our Galaxy. This should provide significant benefits, such as the crucial insight needed to interpret future sensitive, high-resolution surveys with next generation, globe-spanning telescopes in which Australia is a key partner.Read moreRead less
Stochastic Methods in Mathematical Geophysical Fluid Dynamics. The project will develop analytical and numerical methods for long-term weather forecasting and climate modelling. The project deals with the mathematical aspects and fundamental mechanisms underpinning numerical climate forecasting. The project will develop new methodology for accurate modelling of the important and dominant slow global processes without explicitly resolving the precise detail of the weather of each day at all scale ....Stochastic Methods in Mathematical Geophysical Fluid Dynamics. The project will develop analytical and numerical methods for long-term weather forecasting and climate modelling. The project deals with the mathematical aspects and fundamental mechanisms underpinning numerical climate forecasting. The project will develop new methodology for accurate modelling of the important and dominant slow global processes without explicitly resolving the precise detail of the weather of each day at all scales. Using sophisticated mathematics, this project investigates how to parameterize the fast and small processes by using stochastic processes in a controllable and adaptive way.Read moreRead less
Plasmonic nanoparticle catalysis for nitrogen-based synthesis. Light can generate an optical force to capture small objects. This requires intense light – a laser, which limits optical trapping in catalysis applications. This project aims to apply plasmonic nanoparticles with normal-intensity light to take advantage of plasmonic-generated optical forces for catalytic chemical synthesis. The optical trapping/releasing of small molecules is highly selective and responsive to molecule structure and ....Plasmonic nanoparticle catalysis for nitrogen-based synthesis. Light can generate an optical force to capture small objects. This requires intense light – a laser, which limits optical trapping in catalysis applications. This project aims to apply plasmonic nanoparticles with normal-intensity light to take advantage of plasmonic-generated optical forces for catalytic chemical synthesis. The optical trapping/releasing of small molecules is highly selective and responsive to molecule structure and so presents a great opportunity to radically alter chemical synthesis pathways, which will be illustrated with reactions on liquid-solid and gas-solid interfaces. This highly innovative strategy will be used to discover new nitrogen-based syntheses which are both fundamentally and industrially important.Read moreRead less
Direct simulation of composite microstructures in fluid and elastic media. The proposed innovative computational methodology will improve the design and performance of a wide range of mechanisms and industrial processes involving particulate inclusions, from engineering to biological applications. The resultant technology will make a contribution to maintain and enhance Australia's role in the development of advanced engineering materials through manipulating their composite microstructures. The ....Direct simulation of composite microstructures in fluid and elastic media. The proposed innovative computational methodology will improve the design and performance of a wide range of mechanisms and industrial processes involving particulate inclusions, from engineering to biological applications. The resultant technology will make a contribution to maintain and enhance Australia's role in the development of advanced engineering materials through manipulating their composite microstructures. The proposed computational method will also lead to new opportunities for Australian companies that develop computer simulation software. Our researchers in computational mechanics will gain further opportunities to extend the advances this project will make.Read moreRead less
Cosmic origins: How do galaxies build chemical complexity over cosmic time? This project aims to answer questions of how the chemical complexity required to form stars, planets and life arose through cosmic history. Galaxies are the chemical factories of the Universe. Over the life of the cosmos, they have built reservoirs of the elements required to make stars and planets. Yet we have no complete theory of how this process unfolds or how different galaxy types form. By using advanced instrument ....Cosmic origins: How do galaxies build chemical complexity over cosmic time? This project aims to answer questions of how the chemical complexity required to form stars, planets and life arose through cosmic history. Galaxies are the chemical factories of the Universe. Over the life of the cosmos, they have built reservoirs of the elements required to make stars and planets. Yet we have no complete theory of how this process unfolds or how different galaxy types form. By using advanced instrumentation and developing innovative computational techniques, this project aims to use the motions and chemistry of stars to map the history of galaxies in a new way. This would establish where and when stars formed in different galaxies, revealing the importance of black holes, dark matter, galaxy collisions and local environment in the build-up of chemical complexity in our Universe.Read moreRead less
The impact of impact: what stops star formation in cluster galaxies? This project aims to explain the fundamental differences observed in the star forming properties of galaxies in high and low density environments. This will be achieved by using innovative technology to observe the spatially resolved star forming properties of galaxies in clusters of galaxies, the densest and most extreme environments. These observations will be coupled with a new method for defining galaxy environments, which ....The impact of impact: what stops star formation in cluster galaxies? This project aims to explain the fundamental differences observed in the star forming properties of galaxies in high and low density environments. This will be achieved by using innovative technology to observe the spatially resolved star forming properties of galaxies in clusters of galaxies, the densest and most extreme environments. These observations will be coupled with a new method for defining galaxy environments, which is based on physical properties. The combination of these techniques will be used to establish the degree to which the physical mechanisms acting in clusters impact the star forming properties of infalling galaxies. This will significantly advance understandings of the impact of environment on galaxy evolution.Read moreRead less
Monster galaxies: Extreme limits on galaxy formation. Despite decades of observation, simulations and modelling, the growth and history of the most massive galaxies in the Universe still cannot be explained. This project aims to use massive galaxies identified in the latest generation of galaxy surveys, combined with the latest technology for measuring detailed galaxy properties, to resolve the question of how these galaxies have grown in mass over the last 3 billion years.