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
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
Boron Nitrogen Isostere-Doped Organometallics for Molecular Electronics. The challenge of connecting two or more metals by a single chain of carbon atoms attracts intense study, thereby mimicking electronic circuitry at the molecular level. BN-Isosteric compounds involve selectively replacing (doping) carbon atoms with the elements boron (B) and nitrogen (N). These unprecedented materials should emulate and likely exceed the properties of all-carbon systems. This project aims to design and s .... Boron Nitrogen Isostere-Doped Organometallics for Molecular Electronics. The challenge of connecting two or more metals by a single chain of carbon atoms attracts intense study, thereby mimicking electronic circuitry at the molecular level. BN-Isosteric compounds involve selectively replacing (doping) carbon atoms with the elements boron (B) and nitrogen (N). These unprecedented materials should emulate and likely exceed the properties of all-carbon systems. This project aims to design and synthesise the first molecular BN-isosteric carbon-wire materials including examples based on metal-carbon multiple bonding. Expected outcomes beyond their isolation include high-level interrogation of the structure-function behaviour of their electrical and optical properties relevant to the technologies that will emerge.Read moreRead less
A top-down approach to synthesising high-value fluorocarbons. Fluorocarbons' ability to impart high stability, solubility, and unique reactivity to host molecules renders them invaluable in agrochemicals, pharmaceuticals, polymers and surfactants. Their robustness also renders them environmentally persistent. There are no industrially utilised methods for the re-purposing or recycling of fluorocarbons. This project aims to generate new methods for the selective activation of carbon-fluorine bond ....A top-down approach to synthesising high-value fluorocarbons. Fluorocarbons' ability to impart high stability, solubility, and unique reactivity to host molecules renders them invaluable in agrochemicals, pharmaceuticals, polymers and surfactants. Their robustness also renders them environmentally persistent. There are no industrially utilised methods for the re-purposing or recycling of fluorocarbons. This project aims to generate new methods for the selective activation of carbon-fluorine bonds in polyfluorocarbons, allowing their incorporation or repurposing into high value chemicals and/or easy derivitisation to access a plethora of new fluorocarbon products. Expected outcomes will allow new processing methods to value add to fluorocarbons while preventing their environmental release. Read moreRead less