Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100054
Funder
Australian Research Council
Funding Amount
$1,341,398.00
Summary
Dedicated High-throughput 3D-Electron Diffractometer. This proposal aims to install the first dedicated high-throughput 3D-electron diffractometer in the Southern Hemisphere, and one of the first in the world. It will be able to rapidly solve the atomic-scale structures of molecules and materials for which this is now extremely difficult and time-consuming – or impossible – due to the inability to grow large enough crystals for traditional X-ray diffraction. It will thus provide a significant ad ....Dedicated High-throughput 3D-Electron Diffractometer. This proposal aims to install the first dedicated high-throughput 3D-electron diffractometer in the Southern Hemisphere, and one of the first in the world. It will be able to rapidly solve the atomic-scale structures of molecules and materials for which this is now extremely difficult and time-consuming – or impossible – due to the inability to grow large enough crystals for traditional X-ray diffraction. It will thus provide a significant advantage for chemists, physicists, biologists, geologists, and engineers who rely on detailed structural knowledge to rationally optimise the properties of their compounds, from pharmaceutical activity to carbon capture to superconductivity, to the substantial benefit of multiple national priority areas.Read moreRead less
Nanostructured solid acid catalysts for sustainable chemical manufacturing. This project aims to develop next-generation solid acid catalysts for energy- and atom-efficient transformations of waste biomass and carbon dioxide to sustainable chemicals and fuels. Catalysis is a transformative technology, key to both life and lifestyle, contributing to 90% of chemical manufacturing processes and >20% of all industrial products, and will be a key enabler for the emerging Australian bioeconomy. The ex ....Nanostructured solid acid catalysts for sustainable chemical manufacturing. This project aims to develop next-generation solid acid catalysts for energy- and atom-efficient transformations of waste biomass and carbon dioxide to sustainable chemicals and fuels. Catalysis is a transformative technology, key to both life and lifestyle, contributing to 90% of chemical manufacturing processes and >20% of all industrial products, and will be a key enabler for the emerging Australian bioeconomy. The expected development of new high performance catalysts for the production of renewable transportation fuels and sustainable chemical feedstocks will underpin commercially viable low carbon technologies using waste resources, and should provide significant benefits to Australian science, industry, and the environment.
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Beyond structure - solving conformational dynamics for intractable proteins. Proteins perform almost every task that enables the amazing complexity of cellular and whole organism physiology. These molecular machines perform this incredible array of tasks due to their ability to dynamically change shape. For the vast majority of these machines, we can only view a snapshot of the possible shapes they can adopt and can’t monitor how they change from one shape to another, which is critical for their ....Beyond structure - solving conformational dynamics for intractable proteins. Proteins perform almost every task that enables the amazing complexity of cellular and whole organism physiology. These molecular machines perform this incredible array of tasks due to their ability to dynamically change shape. For the vast majority of these machines, we can only view a snapshot of the possible shapes they can adopt and can’t monitor how they change from one shape to another, which is critical for their functioning. This project aims to develop and apply a completely new method to visualise dynamic changes in protein shape which is not possible with current techniques. This will allow us to provide a new description and understanding of the function of proteins, which is fundamental to all biology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100100
Funder
Australian Research Council
Funding Amount
$975,934.00
Summary
Multifunctional Platform for Chemical Manufacturing and Energy Materials. We aim to establish the first platform in Australia for the continuous production and in-situ characterisation of molecules and nanomaterials. This project expects to generate new knowledge in the area of functional materials using an interdisciplinary approach. The expected outcomes will be a unique analytical capability for rapid screening of synthetic and operational parameters, and unprecedented fundamental insight int ....Multifunctional Platform for Chemical Manufacturing and Energy Materials. We aim to establish the first platform in Australia for the continuous production and in-situ characterisation of molecules and nanomaterials. This project expects to generate new knowledge in the area of functional materials using an interdisciplinary approach. The expected outcomes will be a unique analytical capability for rapid screening of synthetic and operational parameters, and unprecedented fundamental insight into chemical reactions to inform the design and development of sustainable chemical processes. This proposal will provide significant benefits to cutting-edge research in catalysis, polymer engineering, separation science, CO2 capture and organic synthesis, to positively impact on the energy-manufacturing-environment nexus.Read moreRead less
Design and Fabrication of 2D Hybrid Materials. There are >300 2D materials like graphene with potentially exotic and useful electrooptic and superconductor properties that will drive novel industrial applications. This project aims to use advanced computational and experimental techniques to discover and fabricate new 2D hybrid materials built from different layers of 2D materials. This approach is essential as the number of possible hybrids is huge (millions) and current processes to identify a ....Design and Fabrication of 2D Hybrid Materials. There are >300 2D materials like graphene with potentially exotic and useful electrooptic and superconductor properties that will drive novel industrial applications. This project aims to use advanced computational and experimental techniques to discover and fabricate new 2D hybrid materials built from different layers of 2D materials. This approach is essential as the number of possible hybrids is huge (millions) and current processes to identify and build 2D hybrids are technically challenging and slow. Expected outcomes include defining a new paradigm for efficient identification and synthesis of 2D hybrids with exotic, bespoke properties. The generation of a large database of materials for researchers/industry would be of wide benefit.Read moreRead less
Advancing the chemistry of rare earths - an Australian resource. This project aims to advance knowledge of the synthesis, structures and reactivity of highly reactive rare earth metal-organic compounds. The project expects to build the knowledge and skills to underpin many developments of Australia's still under utilized rare earth resources to diversify from Chinese domination. The anticipated outcomes will be new synthetic and reaction chemistry including a demonstration of how size and electr ....Advancing the chemistry of rare earths - an Australian resource. This project aims to advance knowledge of the synthesis, structures and reactivity of highly reactive rare earth metal-organic compounds. The project expects to build the knowledge and skills to underpin many developments of Australia's still under utilized rare earth resources to diversify from Chinese domination. The anticipated outcomes will be new synthetic and reaction chemistry including a demonstration of how size and electronic factors can be used to modify and advance rare earth chemistry. This project should provide significant benefit such as are a better knowledge base in rare earth chemistry to underpin future applications in chemical manufacturing, new materials, catalysis and recycling.Read moreRead less
A structure-based design approach to maximising targeting interactions. This project aims to build on a highly successful collaboration between the Australian biotechnology company Starpharma and Monash University, to better understand the design of next generation nanomaterials that home to specific target cells. The project seeks to capitalize on recent advances in dendrimer chemistry and protein engineering to explore the design of nanomaterials linked to engineered antibody fragments. The an ....A structure-based design approach to maximising targeting interactions. This project aims to build on a highly successful collaboration between the Australian biotechnology company Starpharma and Monash University, to better understand the design of next generation nanomaterials that home to specific target cells. The project seeks to capitalize on recent advances in dendrimer chemistry and protein engineering to explore the design of nanomaterials linked to engineered antibody fragments. The anticipated goal is attainment of exquisite, cell specific targeting affinity. Targeted nanomaterials have the potential to transform the clarity of imaging technologies; to facilitate the design of sensors and diagnostics that detect biochemical change in highly select cell populations and to revolutionise drug delivery.Read moreRead less
Improved monitoring of aquatic pollutants in national water resources. Clean water is predicted to become the world’s most valuable asset during this century, necessitating the improved monitoring of Australia’s limited water resources. Using a new and integrated monitoring approach, this project expects to develop and implement novel passive sampling technologies to monitor a range of water pollutants, specifically toxic ionised organic chemicals of emerging concern. The outcomes of this projec ....Improved monitoring of aquatic pollutants in national water resources. Clean water is predicted to become the world’s most valuable asset during this century, necessitating the improved monitoring of Australia’s limited water resources. Using a new and integrated monitoring approach, this project expects to develop and implement novel passive sampling technologies to monitor a range of water pollutants, specifically toxic ionised organic chemicals of emerging concern. The outcomes of this project will create cost-effective tools to advance the detection of emerging chemicals in drinking, ground, surface and waste waters. The technology will benefit millions of Australians by safeguarding essential water resources.Read moreRead less
Reactivity and photochemistry of halide anions: atmospheric implications. Bromine and iodine are suspected to be responsible for most of the halogen-induced ozone loss in the stratosphere but are not currently included in atmospheric models due to a paucity of knowledge of the gas-phase chemistry and photochemistry of their anions and radicals. This project will develop and deploy advanced mass spectrometry and laser spectroscopy techniques to enable precision measurements of the reactions and p ....Reactivity and photochemistry of halide anions: atmospheric implications. Bromine and iodine are suspected to be responsible for most of the halogen-induced ozone loss in the stratosphere but are not currently included in atmospheric models due to a paucity of knowledge of the gas-phase chemistry and photochemistry of their anions and radicals. This project will develop and deploy advanced mass spectrometry and laser spectroscopy techniques to enable precision measurements of the reactions and photo-reactions of gas-phase iodide and bromide anions and their oxides. These state-of-the-art measurements of reaction kinetics and products will enable accurate chemical models that predict the impact of bromine and iodine chemistry on ozone levels and will inform future models for global climate.Read moreRead less