Challenging targets in rare earth metal-organic chemistry. This project aims to prepare highly reactive rare earth organometallic and metal-organic compounds, especially from the free metals, and to determine their structures and reactivity. Abundant rare earth resources position Australia to be a major supplier of these strategic elements. The challenging target systems include coordination stabilised novel ligands, pseudo-Grignard reagents LnR(X) including the rare fluorides, complexes primed ....Challenging targets in rare earth metal-organic chemistry. This project aims to prepare highly reactive rare earth organometallic and metal-organic compounds, especially from the free metals, and to determine their structures and reactivity. Abundant rare earth resources position Australia to be a major supplier of these strategic elements. The challenging target systems include coordination stabilised novel ligands, pseudo-Grignard reagents LnR(X) including the rare fluorides, complexes primed for carbon-fluorine activation, and intermediates from use of lanthanoid reagents in organic synthesis. The project will provide a knowledge base and expertise for the utilisation of Australia's abundant rare earths and will transform the current behaviour of the elements. It builds the expertise and knowledge needed to underpin Australian rare earth processing and develops the breakthrough science needed for new applications in fine chemical manufacturing, catalysis and recycling.Read moreRead less
Advancing the chemistry of topical rare earth metals. Abundant rare earth resources positions Australia to be a major supplier of these strategic elements and overcome the shortage created by the Chinese monopoly and export restrictions. This project will build the expertise and knowledge needed to underpin Australian rare earth processing and develop the breakthrough science needed for new applications.
Targeting Bio-Compatible Homo- and Hetero-bimetallic Cages and their Application in High Energy and Dual Energy Computed Tomography. The project is focused on the synthesis, characterisation and stability of novel homo-metallic and hetero-metallic oxygen and sulfur based cage compounds which have the potential to be suitable for high energy and Dual Energy CT imaging (DECT), and also for optical imaging where rare-earth metals are involved. Pre-requisites for cage design are that they be stable ....Targeting Bio-Compatible Homo- and Hetero-bimetallic Cages and their Application in High Energy and Dual Energy Computed Tomography. The project is focused on the synthesis, characterisation and stability of novel homo-metallic and hetero-metallic oxygen and sulfur based cage compounds which have the potential to be suitable for high energy and Dual Energy CT imaging (DECT), and also for optical imaging where rare-earth metals are involved. Pre-requisites for cage design are that they be stable and soluble in aqueous media, and be resistant to anionic ligand exchange at the cluster surface. The targeted metals are based on good attenuation at high (100 to 140 keV) and low X-ray (less than 30 keV) energies, and the possibility of high stability and low toxicity.Read moreRead less
Reactive metal-organics embracing the rare earth and alkaline earth metals. This project aims to study the structure and reactions of highly reactive rare earth/lanthanoid and heavy alkaline earth (calcium, strontium, barium) organometallic and metal–organic compounds. The target systems include pseudo-Grignard reagents Ln(Ae)R(X) including the rare fluorides, intermediates from use of lanthanoid reagents in organic synthesis, compounds in unusual high oxidation states, complexes primed for carb ....Reactive metal-organics embracing the rare earth and alkaline earth metals. This project aims to study the structure and reactions of highly reactive rare earth/lanthanoid and heavy alkaline earth (calcium, strontium, barium) organometallic and metal–organic compounds. The target systems include pseudo-Grignard reagents Ln(Ae)R(X) including the rare fluorides, intermediates from use of lanthanoid reagents in organic synthesis, compounds in unusual high oxidation states, complexes primed for carbon–fluorine activation, and Ln(Ae)/Al bimetallics as isoprene polymerisation catalysts. Abundant rare earth resources position Australia to be a major supplier of these strategic elements. The project aims to develop the knowledge base and expertise needed to underpin the use of Australia's abundant rare earth and calcium resources in chemical manufacture, catalysis and recycling.Read moreRead less