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Integrated approach to self assembled molecular capsules. Process intensification technologies in the form of spinning disc and rotating tube processing are new to Australia and present many opportunities for both carrying out the synthesis of organic compounds and in fabricating nanomaterials. The ensuing nanotechnological applications are more benign in approach then other fabrication techniques, minimising the generation of waste at the same time under continuous flow which is likely to be mo ....Integrated approach to self assembled molecular capsules. Process intensification technologies in the form of spinning disc and rotating tube processing are new to Australia and present many opportunities for both carrying out the synthesis of organic compounds and in fabricating nanomaterials. The ensuing nanotechnological applications are more benign in approach then other fabrication techniques, minimising the generation of waste at the same time under continuous flow which is likely to be more attractive to industry. Proposed applications such as drug delivery, catalysis, smart materials and device technology are expected to foster industrial collaborations. The project will provide first-rate research training and promote Australian science through the development of these new technologies.Read moreRead less
Integrated self assembly processes and spinning disc reactor technology. Spinning Disc Reactor technology is new to Australia and will have wide ranging applications in nano-technology and in developing benign industrial chemical processes with smaller footprint and significantly reduced capital outlay. The cutting edge research will foster collaboration with industry, and lead to establishing new industries in device technology, smart materials, health care products, catalysis and energy storag ....Integrated self assembly processes and spinning disc reactor technology. Spinning Disc Reactor technology is new to Australia and will have wide ranging applications in nano-technology and in developing benign industrial chemical processes with smaller footprint and significantly reduced capital outlay. The cutting edge research will foster collaboration with industry, and lead to establishing new industries in device technology, smart materials, health care products, catalysis and energy storage, through exploiting commercial opportunities. The project will provide excellent research training in a range of scientific skills and in professional development, and will involve overseas PhD exchange programs. The exciting research incorporating benign metrics will enhance public opinion towards science. Read moreRead less
Crowns, cages and cavities: Insights into host-guest chemistry from experimental charge density analysis of supramolecular crystals. Supramolecular systems - molecular aggregates - underpin the design and development of materials for a vast number of potential applications, in areas as diverse as catalysis, targeted drug delivery, gas storage, chemical separation, electro-optics and nonlinear optics. They also serve as models for complex phenomena such as self-assembly and ligand-receptor bindin ....Crowns, cages and cavities: Insights into host-guest chemistry from experimental charge density analysis of supramolecular crystals. Supramolecular systems - molecular aggregates - underpin the design and development of materials for a vast number of potential applications, in areas as diverse as catalysis, targeted drug delivery, gas storage, chemical separation, electro-optics and nonlinear optics. They also serve as models for complex phenomena such as self-assembly and ligand-receptor binding. Outcomes will impact on several of the nation's articulated research priorities and, through involvement of postdoctoral fellows and postgraduate students in an international collaboration of this nature, the project contributes directly to producing graduates and researchers familiar with state-of-the-art experimental facilities, both within Australia and overseas.Read moreRead less
Lowering the barriers to a hydrogen technology: What slows proton conductors? When hydrogen burns the only product is water, therefore making it the most attractive form of clean energy. Central to the technological use of hydrogen is the need for a material through which only this element can pass, both so that the energy can be extracted and for purification. At present high temperatures are needed to allow hydrogen to pass through solids that exhibit this sieving property. Through state of th ....Lowering the barriers to a hydrogen technology: What slows proton conductors? When hydrogen burns the only product is water, therefore making it the most attractive form of clean energy. Central to the technological use of hydrogen is the need for a material through which only this element can pass, both so that the energy can be extracted and for purification. At present high temperatures are needed to allow hydrogen to pass through solids that exhibit this sieving property. Through state of the art computational methods the movement through these materials can be observed so that the regions that slow the hydrogen down can be identified. From this understanding it will be possible to design more efficient ways of producing energy that can provide clean air for cities and reliable power for remote communities.Read moreRead less
Special Research Initiatives - Grant ID: SR0354861
Funder
Australian Research Council
Funding Amount
$15,000.00
Summary
Network Australia International. "Network Australia International" will harness the expertise and knowledge of expatriate researchers and tap into their overseas networks. NAI will be a unique portal connecting and re-connecting Australian researchers overseas.
The key objectives of the Network are to:
* identify Australian researchers overseas, especially Young Investigators;
* perform a capability audit on their knowledge, expertise and networks;
* identify potential synergies betw ....Network Australia International. "Network Australia International" will harness the expertise and knowledge of expatriate researchers and tap into their overseas networks. NAI will be a unique portal connecting and re-connecting Australian researchers overseas.
The key objectives of the Network are to:
* identify Australian researchers overseas, especially Young Investigators;
* perform a capability audit on their knowledge, expertise and networks;
* identify potential synergies between Australian and overseas researchers, related to National Research Priorities;
* coordinate collaborative research;
* provide opportunities for Australian postdoctoral fellows overseas;
* communicate and enhance opportunities for permanent and recurring visits by Australian expatriates, and develop new initiatives.
Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346892
Funder
Australian Research Council
Funding Amount
$689,000.00
Summary
Protein Over-Expression/Purification and Macromolecular Structure Determination by X-Ray Diffraction. This proposal seeks funds for state-of-the-art facilities for protein over-expression and macromolecular X-ray diffraction. This will build upon recent initiatives within the collaborating institutions in the field of Structural Biology. It will enable research groups in Perth to pursue the large-scale production of important proteins and to conduct high-resolution structural studies using X-ray ....Protein Over-Expression/Purification and Macromolecular Structure Determination by X-Ray Diffraction. This proposal seeks funds for state-of-the-art facilities for protein over-expression and macromolecular X-ray diffraction. This will build upon recent initiatives within the collaborating institutions in the field of Structural Biology. It will enable research groups in Perth to pursue the large-scale production of important proteins and to conduct high-resolution structural studies using X-ray crystallographic techniques. This technology, which is one of the most important tools in modern biology, provides unique insights into the chemical mechanisms of biological macromolecules and will significantly enhance a great breadth of biological research in Western Australia.Read moreRead less
Mapping the family tree of carbon nanostructures: investigation of nanoscrolls and herringbones. New avenues of research in carbon science will be explored by defining a family tree of carbon nanostructures showing the relationship between forms. This project will investigate the properties of poorly unexplored relatives of the family; the results have the potential to impact on the choice of a material for a given application.
Unravelling the nanostructure of atmospheric black carbon. Black carbon is the second most important greenhouse forcing agent after carbon dioxide. The global atmospheric effect of black carbon predicted by current climate models is thought to be underestimated by at least 50 per cent, primarily due to uncertainties over the nature of black carbon and the absence of benchmarks. This project aims to use a computational chemistry approach to develop an atomistic model for black carbon. Using these ....Unravelling the nanostructure of atmospheric black carbon. Black carbon is the second most important greenhouse forcing agent after carbon dioxide. The global atmospheric effect of black carbon predicted by current climate models is thought to be underestimated by at least 50 per cent, primarily due to uncertainties over the nature of black carbon and the absence of benchmarks. This project aims to use a computational chemistry approach to develop an atomistic model for black carbon. Using these models, the project will determine the relationship between nanostructure and properties such as optical absorption and melting point.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100148
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
An X-ray scattering facility for bulk and interfacial nanostructure. This project aims to establish an integrated, three-beamline facility for small- and wide-angle x-ray scattering (SWAXS) investigations of nanostructured materials in the bulk phase and at surfaces, focussed on soft and self-assembled materials such as polymers, biomaterials and molecular gels. This facility will act as a node for researchers in and around Sydney, providing research tools and training in small-angle scattering. ....An X-ray scattering facility for bulk and interfacial nanostructure. This project aims to establish an integrated, three-beamline facility for small- and wide-angle x-ray scattering (SWAXS) investigations of nanostructured materials in the bulk phase and at surfaces, focussed on soft and self-assembled materials such as polymers, biomaterials and molecular gels. This facility will act as a node for researchers in and around Sydney, providing research tools and training in small-angle scattering. It will provide cutting-edge research tools and advanced training in small-angle scattering. It is expected to yield important science in its own right, and enable researchers to more effectively use beamlines at Australian and international major research facilities.Read moreRead less
Molecular machines: regulation of the catalysis and rotation of the enzyme ATP synthase. This project aims to elucidate the regulation of the molecular machine ATP synthase. ATP synthase is an enzyme that performs a critical role in all cells - the synthesis of ATP, the universal biological energy currency. It is known that the enzyme operates via rotation of a central stalk which is driven by a hydrogen ion gradient across a membrane. Constructs of this molecule have been envisaged in the desig ....Molecular machines: regulation of the catalysis and rotation of the enzyme ATP synthase. This project aims to elucidate the regulation of the molecular machine ATP synthase. ATP synthase is an enzyme that performs a critical role in all cells - the synthesis of ATP, the universal biological energy currency. It is known that the enzyme operates via rotation of a central stalk which is driven by a hydrogen ion gradient across a membrane. Constructs of this molecule have been envisaged in the design of future biological nano-motors. Our work will provide an understanding of the regulation of this enzyme with potential application in the control of nano-motors.Read moreRead less