Group 13 Mixed Halide-Hydride and Rare Earth Complexes - New Selective Chiral Hydridic or Low Valent Reducing Agents. This project will make a landmark contribution to two areas of metallohydride chemistry. Both studies will utilise and develop metals that have traditionally been mined and exported from these shores while concurrently imported as value added products at vastly inflated cost. This research will identify knock-on applications in order to stem this financial bias. The new paths to ....Group 13 Mixed Halide-Hydride and Rare Earth Complexes - New Selective Chiral Hydridic or Low Valent Reducing Agents. This project will make a landmark contribution to two areas of metallohydride chemistry. Both studies will utilise and develop metals that have traditionally been mined and exported from these shores while concurrently imported as value added products at vastly inflated cost. This research will identify knock-on applications in order to stem this financial bias. The new paths to rare earth (= Ln) hydrides will have broad industrial appeal, particularly for new materials, where, like similar group 13 materials, they may be used in the deposition of Ln films or even as precursors to superconducting solids. It is anticipated industrial collaboration will ensue. Australia will be promoted as a developer and innovator of frontier technologies.Read moreRead less
Enhancing single-molecule magnets. This project aims to design, synthesise and investigate single-molecule magnets that can function at higher temperatures for use in quantum computing and molecular spintronics. Materials science increasingly benefit from molecular approaches, and lanthanoid-based single-molecule magnets could achieve otherwise inaccessible technological developments such as the development of molecular materials for quantum computing and molecular spintronics. Advances in funda ....Enhancing single-molecule magnets. This project aims to design, synthesise and investigate single-molecule magnets that can function at higher temperatures for use in quantum computing and molecular spintronics. Materials science increasingly benefit from molecular approaches, and lanthanoid-based single-molecule magnets could achieve otherwise inaccessible technological developments such as the development of molecular materials for quantum computing and molecular spintronics. Advances in fundamental chemistry are anticipated, and this project is expected to benefit Australia's participation in related high-end technology industries.Read moreRead less
Charge-Controlled Materials for Separations of Important Resources. This project aims to develop new porous materials that are capable of greater molecular discrimination than current technologies. This project expects to advance understanding of fundamental structure-activity relationships in these materials, and synthetic targets will be geared towards materials for industrially or environmentally important chemical separations associated with metal extraction. Expected outcomes of this projec ....Charge-Controlled Materials for Separations of Important Resources. This project aims to develop new porous materials that are capable of greater molecular discrimination than current technologies. This project expects to advance understanding of fundamental structure-activity relationships in these materials, and synthetic targets will be geared towards materials for industrially or environmentally important chemical separations associated with metal extraction. Expected outcomes of this project include new insights on the underlying chemistry for tailoring crystalline microporous materials towards select applications. This should provide significant benefits, such as future low-energy and efficient technologies for industrially important separation processes with reduced financial and environmental costs.Read moreRead less