Extracting the 4f-wavefunction of rare earth magnets from X-ray diffraction. The project aims to develop a new combined computational quantum chemistry and experimental X-ray diffraction protocol to extract the 4f electron wavefunction in lanthanide magnetic materials. Results will be significant for the design and screening of efficient molecule-based magnets. Expected outcomes include detailed understanding of the influence of the chemical and crystal environment on single-molecule magnet prop ....Extracting the 4f-wavefunction of rare earth magnets from X-ray diffraction. The project aims to develop a new combined computational quantum chemistry and experimental X-ray diffraction protocol to extract the 4f electron wavefunction in lanthanide magnetic materials. Results will be significant for the design and screening of efficient molecule-based magnets. Expected outcomes include detailed understanding of the influence of the chemical and crystal environment on single-molecule magnet properties, and benchmarking and development of new computational methods. Significant benefits include focused strategies to design and identify commercially viable lanthanide-based molecular memories, and advance our understanding of the quantum mechanics of strongly correlated 4f electron systems.Read moreRead less
Understanding and improving rare earth corrosion inhibitors. This project aims to investigate rare earth corrosion inhibitors by an interdisciplinary program of chemistry and materials science.
The project will generate new knowledge as to how rare earth corrosion inhibitors function and can be improved.
Expected outcomes include a better understanding of inhibitor induced protective films and improved inhibitors.
Significant benefits are eventually better protection of infrastructure from .... Understanding and improving rare earth corrosion inhibitors. This project aims to investigate rare earth corrosion inhibitors by an interdisciplinary program of chemistry and materials science.
The project will generate new knowledge as to how rare earth corrosion inhibitors function and can be improved.
Expected outcomes include a better understanding of inhibitor induced protective films and improved inhibitors.
Significant benefits are eventually better protection of infrastructure from corrosion with greener inhibitors and a new bulk use for rare earths to aid Australia’s emerging rare earth industry.
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Mitochondrial targeting by a new class of gadolinium agents. This research project will lead to the development of new molecular agents containing the element gadolinium which can selectively accumulate within cell mitochondria, with a long-term application in cutting-edge therapies involving X-rays or neutrons. The lanthanoid element gadolinium offers many unique opportunities for medicinal chemistry and this project will generate new knowledge in bioinorganic chemistry and synchrotron science. ....Mitochondrial targeting by a new class of gadolinium agents. This research project will lead to the development of new molecular agents containing the element gadolinium which can selectively accumulate within cell mitochondria, with a long-term application in cutting-edge therapies involving X-rays or neutrons. The lanthanoid element gadolinium offers many unique opportunities for medicinal chemistry and this project will generate new knowledge in bioinorganic chemistry and synchrotron science. The expected outcomes of this research will address many of the unresolved questions regarding mitochondrially-targeted gadolinium complexes, the first such agents specifically designed for potential long-term application in binary therapies and imaging.Read moreRead less
Programmable Organometallics for Spatiotemporal Light Control. This Project aims to develop new materials that control and modify light. The new organometallics from this Project are anticipated to display world record light intensity-dependent absorption and other phenomena. These new programmable molecules are expected to respond to environmental stimuli with precise spatial control. Anticipated outcomes of this Project include environmental sensors and a technology platform for targeted medic ....Programmable Organometallics for Spatiotemporal Light Control. This Project aims to develop new materials that control and modify light. The new organometallics from this Project are anticipated to display world record light intensity-dependent absorption and other phenomena. These new programmable molecules are expected to respond to environmental stimuli with precise spatial control. Anticipated outcomes of this Project include environmental sensors and a technology platform for targeted medical imaging and light-responsive therapies. This Project should provide significant benefits including possible commercialisation of the new materials, enhanced research capacity, training students and a postdoctoral fellow with unique skills, and the strengthening of research linkages with strategic partners.Read moreRead less
Molecular Spin Switching with Earth Abundant Metals. This project aims to develop molecular materials based on non-precious metals that respond to stimuli, including heat or light, by switching between forms with different properties, such as colour and electrical conductivity. The project expects to deliver enhanced control over the switching characteristics and incorporation of the materials into responsive thin films, ready for integration into devices. These molecular switches are promising ....Molecular Spin Switching with Earth Abundant Metals. This project aims to develop molecular materials based on non-precious metals that respond to stimuli, including heat or light, by switching between forms with different properties, such as colour and electrical conductivity. The project expects to deliver enhanced control over the switching characteristics and incorporation of the materials into responsive thin films, ready for integration into devices. These molecular switches are promising for molecular electronics, spintronics and colour-based sensing and display devices. Their fast response time and small component size imply less heat to dissipate and therefore less electricity required for cooling upon implementation in information communications and other technologies.Read moreRead less