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
Roaming around the Transition State: A New Mechanism of Chemical Reactions. Gas-phase reaction mechanisms are at the core of some of the most important problems facing Australia at present: atmospheric models for CO2 are central to climate change; models of isotope exchange are essential to learn about past climates from Antarctic ice cores; and models of combustion are used to optimise energy efficiency. The mechanisms used in these models rely on accurate chemistry. A newly discovered chemica ....Roaming around the Transition State: A New Mechanism of Chemical Reactions. Gas-phase reaction mechanisms are at the core of some of the most important problems facing Australia at present: atmospheric models for CO2 are central to climate change; models of isotope exchange are essential to learn about past climates from Antarctic ice cores; and models of combustion are used to optimise energy efficiency. The mechanisms used in these models rely on accurate chemistry. A newly discovered chemical mechanism has the potential to change many of the reactions that we currently use in these chemical models. This project will determine how important this new mechanism is, and what its impact is on gas-phase reaction models.Read moreRead less
Special Research Initiatives - Grant ID: SR0354591
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
New Techniques using X-rays, Electrons and Quantum Optics in Physics & Chemistry and key developments for biomedicine & industry. This network will develop theoretical, experimental and computational techniques addressing key issues in physics, chemistry, biology and geosciences. Scope will be wide-ranging and inclusive. We anticipate making major developments in the design and understanding of absolute X-ray Absorption Fine Structure, X-ray, Neutron and Electron Diffraction, Electron Density Ma ....New Techniques using X-rays, Electrons and Quantum Optics in Physics & Chemistry and key developments for biomedicine & industry. This network will develop theoretical, experimental and computational techniques addressing key issues in physics, chemistry, biology and geosciences. Scope will be wide-ranging and inclusive. We anticipate making major developments in the design and understanding of absolute X-ray Absorption Fine Structure, X-ray, Neutron and Electron Diffraction, Electron Density Mapping, Molecular and Cluster computations and Powder Diffraction for fundamental research, biomedical and industrial applications. These breakthroughs will be invaluable for the development of Australia's major research infrastructure (the synchrotron, electron microscopes, and the research reactor). This will develop Australian expertise and collaboration at the cutting edge of a variety of interdisciplinary fields.Read moreRead less
Enhanced biocatalysis in organic solvents for pharmaceutical biotransformation. Enzymes such as hydrolases play an important role in biotechnology because of their extreme versatility with respect to substrate specificity and stereoselectivity. The use of lipases as catalysts for optical isomer-specific organic reactions is often limited by unacceptably low enantioselectivities. We will investigate recombinant enzymes cloned from thermophilic lipolytic bacteria for synthetic reactions in orga ....Enhanced biocatalysis in organic solvents for pharmaceutical biotransformation. Enzymes such as hydrolases play an important role in biotechnology because of their extreme versatility with respect to substrate specificity and stereoselectivity. The use of lipases as catalysts for optical isomer-specific organic reactions is often limited by unacceptably low enantioselectivities. We will investigate recombinant enzymes cloned from thermophilic lipolytic bacteria for synthetic reactions in organic solvents, especially chiral resolution of mixtures in the production of pharmaceutical intermediates. Genetic improvement of lipase enantiospecificity and regioselectivity will be achieved using in vitro evolution by recombination and screening. The outcome will be cost-effective production superior biocatalysts with specifically enhanced regiospecific, enantioselective and hydrolytic characteristics.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100107
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Purchase of a multi-purpose Schottky field emission gun scanning electron microscope. Scanning electron microscopy is a basic analytical tool for imaging surfaces of natural and synthetic materials and identification of nanometre-scale features and their compositions. At the University of Tasmania, it supports four of our six designated priority research themes: Antarctic and Marine Studies, Environment, Frontier Technologies, and Sustainable Primary Production. Our research depending on this te ....Purchase of a multi-purpose Schottky field emission gun scanning electron microscope. Scanning electron microscopy is a basic analytical tool for imaging surfaces of natural and synthetic materials and identification of nanometre-scale features and their compositions. At the University of Tasmania, it supports four of our six designated priority research themes: Antarctic and Marine Studies, Environment, Frontier Technologies, and Sustainable Primary Production. Our research depending on this technique includes many fundamental and applied topics from a wide range of disciplines, such as developing portable detection devices for explosives, finding more efficient and sustainable ways to explore for ore, investigating the effects of climate change on marine ecosystems and improving salinity and drought tolerance of crops.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100010
Funder
Australian Research Council
Funding Amount
$720,000.00
Summary
A 5-D Correlative Imaging Platform: Combining the strengths of light and electron microscopy. This will be Australia's first dedicated five-dimensional multiphoton-microscopy platform, allowing observation of dynamic structures across different length and time scales under controlled temperatures, followed by high-resolution electron microscopy studies on the same samples. This platform will provide a unique characterisation tool to Australia's top-flight investigators, and so contribute to the ....A 5-D Correlative Imaging Platform: Combining the strengths of light and electron microscopy. This will be Australia's first dedicated five-dimensional multiphoton-microscopy platform, allowing observation of dynamic structures across different length and time scales under controlled temperatures, followed by high-resolution electron microscopy studies on the same samples. This platform will provide a unique characterisation tool to Australia's top-flight investigators, and so contribute to the nation's research priorities. It will enable: fundamental studies of cancer, neural diseases and immune disorders; the development of frontier technologies, such as smart nanomaterials, biosensors and targeted drug delivery; and applied research to help plants and soils adapt to climate variability, and to increase sustainable use of water.Read moreRead less