Discovering new organic chemistry using an inorganic touch. This project aims to discover new organic chemistry by treating carbon like a metal atom. Advances in fundamental organic chemistry have been important in developing products, including medicines, plastics and television display technology. Much research activity relies on applying existing organic chemistry, but inventing genuinely new organic chemistry is more difficult. By viewing carbon as a metal, this project will try to solve imp ....Discovering new organic chemistry using an inorganic touch. This project aims to discover new organic chemistry by treating carbon like a metal atom. Advances in fundamental organic chemistry have been important in developing products, including medicines, plastics and television display technology. Much research activity relies on applying existing organic chemistry, but inventing genuinely new organic chemistry is more difficult. By viewing carbon as a metal, this project will try to solve important problems in organic chemistry that have been unresolved for decades, and synthesise valuable chemicals normally generated using expensive precious metal catalysts.Read moreRead less
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
Computational design of high-temperature lanthanide-based molecular magnets. This project aims to improve our knowledge of special molecules pivotal to develop enhanced computer memories, namely Lanthanide Single-Molecule Magnets. The development of faster and more energy-efficient computers crucially depends on increasing their data storage capacity. Harnessing single molecules as tiny magnetic needles to store information is the next fundamental step. Recent findings have seen breakthroughs to ....Computational design of high-temperature lanthanide-based molecular magnets. This project aims to improve our knowledge of special molecules pivotal to develop enhanced computer memories, namely Lanthanide Single-Molecule Magnets. The development of faster and more energy-efficient computers crucially depends on increasing their data storage capacity. Harnessing single molecules as tiny magnetic needles to store information is the next fundamental step. Recent findings have seen breakthroughs towards the development of a commercially viable molecular computer. This project will develop ab-initio computational methods for the systematic rational design of high-temperature lanthanide-based single-molecule magnet materials.Read moreRead less
Shifting the trend in radical battery research . The project aims to address a growing problem of increasing energy consumption by storing intermittent energy from the sun in affordable and efficient flow batteries. The project expects to generate new knowledge in the areas of materials science and battery research by using innovative theoretical chemistry approaches to studying electrochemical properties of nitroxide radicals in ionic media. The project aims to develop radical organic flow batt ....Shifting the trend in radical battery research . The project aims to address a growing problem of increasing energy consumption by storing intermittent energy from the sun in affordable and efficient flow batteries. The project expects to generate new knowledge in the areas of materials science and battery research by using innovative theoretical chemistry approaches to studying electrochemical properties of nitroxide radicals in ionic media. The project aims to develop radical organic flow batteries by utilising ionic liquids to stabilise radicals. Intended outcomes of the project include improved efficiency of flow batteries that can store energy from widely used solar panels. This should provide significant benefits to Australia’s effort to switch to renewable energy technologies. Read moreRead less
Shape-Shifting Molecules: Photoisomerization Action Spectroscopy. This project aims to examine molecules that change shape in response to light in order to gain insight into the biological processes they control. Many biological systems, including the human visual apparatus and bacterial photosynthesis, depend on molecules that change shape in response to light. The project plans to probe shape-shifting molecules with laser light while they are propelled through gas by an electric field. Light-i ....Shape-Shifting Molecules: Photoisomerization Action Spectroscopy. This project aims to examine molecules that change shape in response to light in order to gain insight into the biological processes they control. Many biological systems, including the human visual apparatus and bacterial photosynthesis, depend on molecules that change shape in response to light. The project plans to probe shape-shifting molecules with laser light while they are propelled through gas by an electric field. Light-induced changes in molecular shape produce detectable variations in drift speed. The ensuing knowledge would help calibrate computational approaches for predicting molecular function. It would also establish foundations for understanding essential biological molecules, including retinals, carotenes and peptides, and for developing new light-activated molecular motors and switches.Read moreRead less