Reactivity Enhanced Low-Valent Alkaline Earth Metal Compounds. The project aims to develop highly activated low oxidation state alkaline earth metal complexes as cheap and sustainable alternatives to toxic/expensive late transition metal complexes, that currently dominate the transformation of inert small molecule substrates into value-added organic chemicals. The project expects to generate major fundamental and applied advances in chemistry, using innovative synthetic and computational approac ....Reactivity Enhanced Low-Valent Alkaline Earth Metal Compounds. The project aims to develop highly activated low oxidation state alkaline earth metal complexes as cheap and sustainable alternatives to toxic/expensive late transition metal complexes, that currently dominate the transformation of inert small molecule substrates into value-added organic chemicals. The project expects to generate major fundamental and applied advances in chemistry, using innovative synthetic and computational approaches, and a multidisciplinary collaborative team. Expected outcomes include building of academic and, later, industrial research capacity, knowledge, an international network, and a highly trained workforce. Success should see substantial economic, environmental and societal benefits flowing to Australia.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
Innovations in Green Chemical Manufacture from Synchrotron based Techniques. This project aims to find sustainable ways to produce commodity chemicals by developing new catalysts. New synchrotron techniques will be developed and applied to provide new knowledge about the spatial and temporal factors affecting the selectivity and efficiency of electron transfer, redox reactions and diffusion, key for catalyst design. Expected outcomes include the development of new catalysts, new catalyst design ....Innovations in Green Chemical Manufacture from Synchrotron based Techniques. This project aims to find sustainable ways to produce commodity chemicals by developing new catalysts. New synchrotron techniques will be developed and applied to provide new knowledge about the spatial and temporal factors affecting the selectivity and efficiency of electron transfer, redox reactions and diffusion, key for catalyst design. Expected outcomes include the development of new catalysts, new catalyst design concepts and a knowledge repository/database of analytical observations key for unlocking new materials knowledge. This should provide significant economic and environmental benefits by placing Australia at the forefront of the sustainable production of commodity chemicals.Read moreRead less
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
Data Driven Discovery of New Catalysts for Asymmetric Synthesis. This project aims to discover new catalytic strategies for the synthesis of valuable nitrogen-containing molecules. An innovative approach combining statistical modelling techniques and chemical synthesis tactics will be used to establish a unique platform for predictable catalyst design that significantly accelerates the discovery process. As a result, new organometallic catalysts that efficiently convert simple and readily access ....Data Driven Discovery of New Catalysts for Asymmetric Synthesis. This project aims to discover new catalytic strategies for the synthesis of valuable nitrogen-containing molecules. An innovative approach combining statistical modelling techniques and chemical synthesis tactics will be used to establish a unique platform for predictable catalyst design that significantly accelerates the discovery process. As a result, new organometallic catalysts that efficiently convert simple and readily accessible chemical building blocks into complex chiral amine derivatives in a safer and more cost effective manner will be identified. These new catalytic strategies will be of significant utility, enabling the invention and more sustainable manufacture of agrochemicals, life-saving medicines, and functional materials.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC230100046
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Training Centre for Radiochemical Technologies and Precision Radiopharmaceuticals. This project aims to train the next generation of radiochemists and discover new molecular approaches to harness radioactivity. Novel chemistry exploiting molecular incorporation of radioactive elements, stable chelation of metal radionuclides, bioconjugation methodologies, radioactivity capture via nanomaterials and cages, and the design of new peptidomimetic targeting molecules will deliver technological adv ....ARC Training Centre for Radiochemical Technologies and Precision Radiopharmaceuticals. This project aims to train the next generation of radiochemists and discover new molecular approaches to harness radioactivity. Novel chemistry exploiting molecular incorporation of radioactive elements, stable chelation of metal radionuclides, bioconjugation methodologies, radioactivity capture via nanomaterials and cages, and the design of new peptidomimetic targeting molecules will deliver technological advances to radiopharmaceutical science. Outcomes will include a highly-skilled workforce and enhanced commercial capacity to meet a rapidly escalating global radiopharmaceutical market. This project will provide significant benefits by securing an internal supply chain and know-how for cutting-edge radiochemical technologies.Read moreRead less
Aluminium at the centre of sustainable catalysis. The project aims to establish new directions in the field of Lewis acid catalysis by creating a unique set of aluminium compounds. As catalysis is an important principle of green chemistry and as aluminium is the most abundant metal in the Earth's crust (i.e. sustainable), the project's aims are exceptionally well aligned with the society's targets to alleviate the negative effects of human activities on the environment. Expected outcomes of this ....Aluminium at the centre of sustainable catalysis. The project aims to establish new directions in the field of Lewis acid catalysis by creating a unique set of aluminium compounds. As catalysis is an important principle of green chemistry and as aluminium is the most abundant metal in the Earth's crust (i.e. sustainable), the project's aims are exceptionally well aligned with the society's targets to alleviate the negative effects of human activities on the environment. Expected outcomes of this project include significant advances related to industrially relevant processes, potentially degradable polymers and valorisation of the most prevalent greenhouse gas. Thus, the overall project should provide significant benefit to our collective efforts to mediate human impact on climate change.Read moreRead less
Heavy Metal Chemistry Goes Nuclear: Radioactive Rhenium and Terbium Agents. This project aims to make fundamental advances in the basic knowledge of the bioinorganic chemistry of radioactive metals that have the potential to be used in the future as radioactive drugs. Technological advances in the production of radioactive isotopes of rhenium and terbium have increased the feasibility of using these radionuclides as radioactive drugs, but their use requires new basic knowledge in their fundament ....Heavy Metal Chemistry Goes Nuclear: Radioactive Rhenium and Terbium Agents. This project aims to make fundamental advances in the basic knowledge of the bioinorganic chemistry of radioactive metals that have the potential to be used in the future as radioactive drugs. Technological advances in the production of radioactive isotopes of rhenium and terbium have increased the feasibility of using these radionuclides as radioactive drugs, but their use requires new basic knowledge in their fundamental coordination chemistry. This project will develop new ways to synthesise radioactive rhenium and terbium complexes. The outcomes of this project will be an improved understanding of the coordination chemistry rhenium and terbium which is required to inform their future translation to new radiopharmaceuticals.Read moreRead less
Converting Biomass into Value-Added Catalysts for Water Electrolysis. This project aims to employ agricultural waste to manufacture new highly active and stable non-precious metal catalysts for accelerating hydrogen production from water electrolysis. The project expects to generate new knowledge in the development of low-cost and sustainable catalysts for renewable hydrogen production and new technology for converting agricultural waste into value-added catalysts. The project outcomes are expec ....Converting Biomass into Value-Added Catalysts for Water Electrolysis. This project aims to employ agricultural waste to manufacture new highly active and stable non-precious metal catalysts for accelerating hydrogen production from water electrolysis. The project expects to generate new knowledge in the development of low-cost and sustainable catalysts for renewable hydrogen production and new technology for converting agricultural waste into value-added catalysts. The project outcomes are expected to benefit Australia by creating new commercial opportunities in ‘waste-to-catalyst’ conversion and generating a new pathway for managing and recycling agricultural waste, thus providing both environmental and economic benefits while contributing to a sustainable economy.Read moreRead less