Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239943
Funder
Australian Research Council
Funding Amount
$245,000.00
Summary
Access for Australian Researchers to Advanced Neutron-Beam Technique. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Aus ....Access for Australian Researchers to Advanced Neutron-Beam Technique. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australia's parnership with the world's most intense neutron source, ISIS in the UK, in order to sustain the considerable Australian scientific momentum which now relies on ISIS.
The outcome will be new science that cannot be generated solely within Australia.Read moreRead less
Synthesis and Fundamental Understanding of Low-Dimensional Metal Oxide Nanoparticles for Gas Sensing Application. This project is primarily devoted to material science and nanotechnology, one of the cutting-edge areas in Australia's National Research Priority. Successful completion of this project will result in controlled synthesis, functional assembly and fundamental understanding of low-dimensional metal oxide nanostructures. The research findings will be useful for developing new and complex ....Synthesis and Fundamental Understanding of Low-Dimensional Metal Oxide Nanoparticles for Gas Sensing Application. This project is primarily devoted to material science and nanotechnology, one of the cutting-edge areas in Australia's National Research Priority. Successful completion of this project will result in controlled synthesis, functional assembly and fundamental understanding of low-dimensional metal oxide nanostructures. The research findings will be useful for developing new and complex nanostructures for functional applications in lithium ionic batteries, catalysts and gas sensors. The conduct of this project will significantly expand the knowledge creativity of Australia in advanced materials.
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Reactions of Coordinated Dinitrogen. The program will develop novel metal-based catalysts and reagents that will transform nitrogen gas into ammonia and other nitrogen-containing compounds (nitrogen fixation). This fundamental chemical transformation underpins major chemical industries and this new approach using organometallic catalysts will significantly improve the efficiency of ammonia production and reduce the energy and harsh reaction conditions currently required. This program will desi ....Reactions of Coordinated Dinitrogen. The program will develop novel metal-based catalysts and reagents that will transform nitrogen gas into ammonia and other nitrogen-containing compounds (nitrogen fixation). This fundamental chemical transformation underpins major chemical industries and this new approach using organometallic catalysts will significantly improve the efficiency of ammonia production and reduce the energy and harsh reaction conditions currently required. This program will design catalysts with multiple complementary metal centres tailored to bind and activate nitrogen gas to facilitate its reaction with hydrogen or other reagents.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989127
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of ....A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of option to an existing spectrometer that will broaden its user-base from specialised applications in physics to more general applications in physics, chemistry, materials-science and biology. This additional option provides a totally new way for Australian scientists to study atomic and molecular motions. Read moreRead less
Poly-crystalline Thin Films for LASER Applications. This project is based on a recent discovery which reports LASER emission in disordered media such as polycrystalline ZnO. This behaviour appears to be related to the crystallographic properties of ZnO (wurztite) material. Using a novel deposition process the defect density, size of crystallites and macroscopic orientation within such thin films will be controlled independently. This will provide an opportunity to study the fundamental basis of ....Poly-crystalline Thin Films for LASER Applications. This project is based on a recent discovery which reports LASER emission in disordered media such as polycrystalline ZnO. This behaviour appears to be related to the crystallographic properties of ZnO (wurztite) material. Using a novel deposition process the defect density, size of crystallites and macroscopic orientation within such thin films will be controlled independently. This will provide an opportunity to study the fundamental basis of such behaviour. In conjunction with this the development of structure in similarly produced GaN (wurztite) films will be examined. This work should also provide practical information concerning the potential performance of LASER devices based on disordered materials.Read moreRead less
The Baylis-Hillman Reaction: Asymmetric Organocatalysis and Applications. Many drugs come in two chiral mirror images (enantiomers) where the therapeutic effect is usually associated with only one while the other has no effect or can be harmful as was the case with thalidomide. Chemical reactions that yield just the desired mirror image, or enantiomer, and not the other are therefore in great demand and heavily pursued by the pharmaceutical, fine chemical and materials industries as a frontier ....The Baylis-Hillman Reaction: Asymmetric Organocatalysis and Applications. Many drugs come in two chiral mirror images (enantiomers) where the therapeutic effect is usually associated with only one while the other has no effect or can be harmful as was the case with thalidomide. Chemical reactions that yield just the desired mirror image, or enantiomer, and not the other are therefore in great demand and heavily pursued by the pharmaceutical, fine chemical and materials industries as a frontier technology. This project will result in the development of novel catalytic reactions that allow the synthesis of chiral chemicals in a cost-efficient and green manner needed by many industries, and also training of students with highly desirable synthetic skills to lead the next wave in pharmaceuticals and biotechnology.Read moreRead less
A rational approach to a high-resolution structure of the multidrug transporter EmrE. Membrane proteins form only 0.3% of the available protein structures in the protein data bank (PDB), yet 30% of the proteins in the human genome and 50% of human drug targets are membrane proteins. Multidrug transporters are membrane proteins responsible for antibiotic resistance in humans. A high-resolution structure of a multidrug resistance protein, together with comprehensive biochemical characterization, w ....A rational approach to a high-resolution structure of the multidrug transporter EmrE. Membrane proteins form only 0.3% of the available protein structures in the protein data bank (PDB), yet 30% of the proteins in the human genome and 50% of human drug targets are membrane proteins. Multidrug transporters are membrane proteins responsible for antibiotic resistance in humans. A high-resolution structure of a multidrug resistance protein, together with comprehensive biochemical characterization, would enable a detailed understanding of how these protein functions. Potentially it could also aid in the development of specific inhibitors that would prevent EmrE (and perhaps other similar proteins) from carry out its harmful mission. Read moreRead less
First Principles Design of Second-Generation Protein Stains. Proteomics is an emerging technology which has the potential to revolutionize modern biology and medicine. Extremely sensitive protein stains are a key proteomics technology, and in conjunction with gel electrophoresis, they facilitate the rapid and quantitative detection of all polypeptides in a cell. However, the tools of proteomics must rapidly advance (cheaper, greater sensitivity, more reliable, safer to handle) before the techn ....First Principles Design of Second-Generation Protein Stains. Proteomics is an emerging technology which has the potential to revolutionize modern biology and medicine. Extremely sensitive protein stains are a key proteomics technology, and in conjunction with gel electrophoresis, they facilitate the rapid and quantitative detection of all polypeptides in a cell. However, the tools of proteomics must rapidly advance (cheaper, greater sensitivity, more reliable, safer to handle) before the technology can mature to the stage where its full potential is realized. We will enable the evolution of proteomics by devising second generation fluorescent protein stains, using the environmentally-friendly natural product, epicocconone, as our design platform.Read moreRead less
Persistent Triplet Carbenes. Viable or Not? Triplet carbenes have significant potential real world applications, such as in modern electronics. However, they are highly reactive (lifetimes typically < 1 day), and this has stymied their development. Can I design so called persistent triplet-carbenes, which have significant lifetimes? I will try to using computer chemistry. In doing so, I will provide synthetic chemists with 'high-value' targets for preparation, hence saving tax dollars and minimi ....Persistent Triplet Carbenes. Viable or Not? Triplet carbenes have significant potential real world applications, such as in modern electronics. However, they are highly reactive (lifetimes typically < 1 day), and this has stymied their development. Can I design so called persistent triplet-carbenes, which have significant lifetimes? I will try to using computer chemistry. In doing so, I will provide synthetic chemists with 'high-value' targets for preparation, hence saving tax dollars and minimizing creation of environmentally damaging waste. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883030
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of ....High-Resolution Field Emission Scanning Electron Microscopy (FESEM) Platform for Characterisation at the Nanometre-Level. The Field Emission Scanning Electron Microscope (FESEM) is designed to provide fundamental insights into physical and biological systems though characterisation and analysis of structures on nanometre length scales. This versatile instrument will support a wide range of research projects covering all four national research priorities. These range from the characterisation of light alloys to boost and intensify Australia's aluminium, magnesium and titanium alloy industries, to tissue engineering for the repair of human elastic tissues in skin, artery, bladder and lung, to the study of microtubules in plant cells for genetic manipulation of plants to withstand environmental stresses such as drought or salinity.Read moreRead less