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Discovery Early Career Researcher Award - Grant ID: DE170100200
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Anion-templated functional architectures. This project aims to introduce a method for preparing large, complex materials from relatively simple precursors. Negatively-charged species, anions, will be used to assemble positively-charged organic molecules into three-dimensional structures, including cages and porous framework materials. This will increase fundamental understanding of how anions behave and their use in self-assembly processes. The structures made using this approach are expected to ....Anion-templated functional architectures. This project aims to introduce a method for preparing large, complex materials from relatively simple precursors. Negatively-charged species, anions, will be used to assemble positively-charged organic molecules into three-dimensional structures, including cages and porous framework materials. This will increase fundamental understanding of how anions behave and their use in self-assembly processes. The structures made using this approach are expected to remove dangerous environmental pollutants from water and store the industrially-relevant gases, hydrogen and carbon dioxide. This offers potential applications in clean energy technology (e.g. hydrogen storage for fuel cells) and environmental remediation (carbon dioxide storage, polycyclic aromatic hydrocarbon removal).Read moreRead less
Switchable molecules for molecular nanoscience. This project targets the development and exploration of switchable molecules for future nanoscale devices. Applications will include individual molecules as: units of magnetic memory for high density data storage, quantum bits in quantum computers, components in electronic devices and switching units in display media.
Processing Pearl Nacre for Bio-Nanotechnology. Nanotechnology has exciting potential to solve major health challenges of the 21st century. The proposed research focuses on developing health care products, derived from a renewable waste stream resource from the pearling industry, en route to establishing products to benefit the rural community, and beyond. The processed pearl nacre provides the possibility of alleviating problems associated with neurotrauma following injury, and for skin regenera ....Processing Pearl Nacre for Bio-Nanotechnology. Nanotechnology has exciting potential to solve major health challenges of the 21st century. The proposed research focuses on developing health care products, derived from a renewable waste stream resource from the pearling industry, en route to establishing products to benefit the rural community, and beyond. The processed pearl nacre provides the possibility of alleviating problems associated with neurotrauma following injury, and for skin regeneration following burns. The recently established powerful multidisciplinary research team in partnership with Pearl Technology combines expertise in chemical processing, nanotechnology, biochemistry, neuroscience and tissue engineering, also providing a basis for quality research training.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100144
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
Advanced X-ray facility for structural elucidation and photocrystallography. This project aims to establish an advanced photocrystallography X-ray facility. Accurately determining molecular structure and understanding how molecules interact with light is important to design and optimise new materials. Normally, measurements to elucidate these properties have to be done separately, making structure-property correlations difficult. The facility will allow the creation of new materials with applica ....Advanced X-ray facility for structural elucidation and photocrystallography. This project aims to establish an advanced photocrystallography X-ray facility. Accurately determining molecular structure and understanding how molecules interact with light is important to design and optimise new materials. Normally, measurements to elucidate these properties have to be done separately, making structure-property correlations difficult. The facility will allow the creation of new materials with application in pharmaceuticals, separation science, organic optoelectronics and magnetic materials. The facility will build capacity in X-ray techniques, create collaborations and provide a unique training ground for students and Early Career Researchers. The advances in materials innovation will strengthen the future viability of Australian industries and manufacturing innovation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100148
Funder
Australian Research Council
Funding Amount
$1,350,000.00
Summary
Advanced Nuclear Magnetic Resonance Technologies for Southeast Queensland. This project aims to establish an advanced Nuclear Magnetic Resonance capability and capacity at two of Queenslands' leading research intensive universities. The project expects to enhance the scope and productivity of hundreds of research projects spanning natural products, synthetic, medicinal, materials and environmental science. Expected outcomes include smarter science, more productive collaborations and superior res ....Advanced Nuclear Magnetic Resonance Technologies for Southeast Queensland. This project aims to establish an advanced Nuclear Magnetic Resonance capability and capacity at two of Queenslands' leading research intensive universities. The project expects to enhance the scope and productivity of hundreds of research projects spanning natural products, synthetic, medicinal, materials and environmental science. Expected outcomes include smarter science, more productive collaborations and superior research training, leading to innovative solutions to challenging problems that confront science and society. This investment should provide significant benefits in the form of new knowledge across multiple disciplines, informing the design of future medicines, agrochemicals, materials and other products.
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Flexible molecular crystals: single crystals that bend, stretch and twist. This project aims to thoroughly quantify the elastic flexibility of a suite of metal-organic molecular crystals. Since antiquity, crystalline materials have been thought to be brittle and inflexible. Crystals can, in fact, display appreciable, even remarkable, elasticity. Some crystals can bend, stretch and twist. The influence that the molecules, and their arrangements in crystals, have on the extent of elasticity will b ....Flexible molecular crystals: single crystals that bend, stretch and twist. This project aims to thoroughly quantify the elastic flexibility of a suite of metal-organic molecular crystals. Since antiquity, crystalline materials have been thought to be brittle and inflexible. Crystals can, in fact, display appreciable, even remarkable, elasticity. Some crystals can bend, stretch and twist. The influence that the molecules, and their arrangements in crystals, have on the extent of elasticity will be determined along with molecular-scale mechanisms for contortion. This information will be used to design new crystals with predictable and tunable elasticity for potential applications previously considered impossible for crystalline materials.Read moreRead less
Polymer nanodiscs. This project aims to produce disc-shaped polymer nanomaterials by utilising a new self-assembly concept based on oppositely charged polymers. This project expects to generate a modular technology that allows synthesis and control over the geometry and functionality of polymer nanoparticles. This level of control will permit a precise investigation of polymer nanodisc properties for nanomedicine applications. Expected outcomes of this project will be the fundamental understandi ....Polymer nanodiscs. This project aims to produce disc-shaped polymer nanomaterials by utilising a new self-assembly concept based on oppositely charged polymers. This project expects to generate a modular technology that allows synthesis and control over the geometry and functionality of polymer nanoparticles. This level of control will permit a precise investigation of polymer nanodisc properties for nanomedicine applications. Expected outcomes of this project will be the fundamental understanding of how nanoparticle geometry affects particle-cell interaction and how nanoscale polymer discs can be used to mimic biological nanoparticles in shape and function.Read moreRead less
The development of yoctowells on magnetic nanoparticles as both tiny chemical reactors and biological models. This project seeks to develop an innovative and cutting-edge research program in biomimicry by studying a surface functionalised system - the so called yoctowells - on magnetic nanoparticles, by studying their inclusion behaviour and utilising the intrinsic magnetic properties for isolation and manipulation in catalysis, medicine and electronics.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100141
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
High resolution nuclear magnetic resonance spectroscopy for glycomics, metabonomics and soft materials applications. This project will enhance the nuclear magnetic resonance spectroscopy capabilities and the world class research being undertaken at the Institute for Glycomics, Griffith University and Queensland University of Technology. This powerful technique can contribute information in diverse research areas such as glycomics, metabonomics and soft materials research.
Designing dendrimer-based lymphatic drug vectors as improved treatments for metastatic cancer. This project builds on areas of research strength in Australia (nanotechnology and biotechnology/biomaterials) and will add considerably to the expanding Australian expertise-base in dendrimer technology (in which it is a world leader). The project will advance the fundamental science base that underpins dendrimer design and has the potential to deliver substantial benefits in improved drug delivery an ....Designing dendrimer-based lymphatic drug vectors as improved treatments for metastatic cancer. This project builds on areas of research strength in Australia (nanotechnology and biotechnology/biomaterials) and will add considerably to the expanding Australian expertise-base in dendrimer technology (in which it is a world leader). The project will advance the fundamental science base that underpins dendrimer design and has the potential to deliver substantial benefits in improved drug delivery and therefore health outcomes for Australia. The interdisciplinary nature of this project will also result in a unique training program for the researchers involved. Such experience is in great demand in Australia where the developing biotechnology and nanotechnology industry is critically short of scientists with skills in drug delivery.Read moreRead less