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C-H to C-F using electrochemistry and gold catalysis. Gold offers great potential in chemical catalysis and this project will use a fascinating new class of gold compounds discovered by the CIs, to develop novel catalysts. Using this chemistry a series of gold(III) compounds with fluoride ligands will be prepared. The catalytic properties of these molecules will then be explored, with a particular focus on adding value to arene hydrocarbons. The ultimate goal of the project is development of new ....C-H to C-F using electrochemistry and gold catalysis. Gold offers great potential in chemical catalysis and this project will use a fascinating new class of gold compounds discovered by the CIs, to develop novel catalysts. Using this chemistry a series of gold(III) compounds with fluoride ligands will be prepared. The catalytic properties of these molecules will then be explored, with a particular focus on adding value to arene hydrocarbons. The ultimate goal of the project is development of new catalysts for the formation of carbon-fluorine bonds and the selective fluorination of organic
compounds. Fluorinated organic molecules are of critical importance in medicinal chemistry and new catalysts of this type offers the potential for better synthesis of medicines and diagnostic agents.Read moreRead less
Mycobacterial Cholesterol Degradation: A Unique Metabolic Weakness? This project aims to understand the use of the steroid cholesterol as a source of essential metabolic building blocks by bacteria. Cholesterol utilisation is a key feature of many bacterial pathogens which have evolved to survive in niche environments. By understanding the initial step in cholesterol degradation and the bioinorganic and bioorganic chemistry of the metalloenzymes that catalyse it, this work aims to develop strate ....Mycobacterial Cholesterol Degradation: A Unique Metabolic Weakness? This project aims to understand the use of the steroid cholesterol as a source of essential metabolic building blocks by bacteria. Cholesterol utilisation is a key feature of many bacterial pathogens which have evolved to survive in niche environments. By understanding the initial step in cholesterol degradation and the bioinorganic and bioorganic chemistry of the metalloenzymes that catalyse it, this work aims to develop strategies to block this activity. This will turn a key strength of these bacteria into a potent weakness and will generate the proof of principle and knowledge required for the future development of effective strategies to combat pathogenic bacteria.Read moreRead less
Electrochemically activated solid state chemistry: A new synthetic avenue. This project aims to validate a new solid state synthetic route discovered in our group by understanding the reaction mechanism and experimenting with the parameter space of reaction variables. The discovery of a new solid state synthetic route opens up a world of possibility for the generation of new materials with a diverse range of potential functions and applications. The fundamental understanding of the reaction mech ....Electrochemically activated solid state chemistry: A new synthetic avenue. This project aims to validate a new solid state synthetic route discovered in our group by understanding the reaction mechanism and experimenting with the parameter space of reaction variables. The discovery of a new solid state synthetic route opens up a world of possibility for the generation of new materials with a diverse range of potential functions and applications. The fundamental understanding of the reaction mechanism will enable the rapid and widespread use of this synthetic route.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101168
Funder
Australian Research Council
Funding Amount
$430,000.00
Summary
Shining a light on the mechanism of photochemical hydrogen production. This project aims to improve the performance and longevity of molecular photocatalysts to produce hydrogen from water and visible light. Sustainable alternatives to fossils fuels, such as hydrogen, are critical to minimising the effects of climate change. This project expects to use innovative experimental techniques to reveal the causes of degradation in key intermediates of the photocatalytic reaction. Understanding these d ....Shining a light on the mechanism of photochemical hydrogen production. This project aims to improve the performance and longevity of molecular photocatalysts to produce hydrogen from water and visible light. Sustainable alternatives to fossils fuels, such as hydrogen, are critical to minimising the effects of climate change. This project expects to use innovative experimental techniques to reveal the causes of degradation in key intermediates of the photocatalytic reaction. Understanding these detrimental pathways can then direct the design of new catalysts with enhanced stability and activity. The fundamental chemistry explored in this project should advance breakthroughs in artificial photosynthesis and provide cleaner methods of hydrogen production under mild conditions, using earth-abundant catalysts.Read moreRead less
Bioelectrochemical interconversion of the building blocks of life. This project aims to harness the efficiency of enzymes (Nature’s catalysts) by coupling them with an electrode for the electrochemical interconversion of carbon dioxide, carbon monoxide and formate; the organic building blocks of life. The significance of this research is that the efficient capture and reduction of carbon dioxide is an important quest in the environment and energy sectors. The expected outcomes of this project wi ....Bioelectrochemical interconversion of the building blocks of life. This project aims to harness the efficiency of enzymes (Nature’s catalysts) by coupling them with an electrode for the electrochemical interconversion of carbon dioxide, carbon monoxide and formate; the organic building blocks of life. The significance of this research is that the efficient capture and reduction of carbon dioxide is an important quest in the environment and energy sectors. The expected outcomes of this project will be an understanding of the reactivity of these enzymes and the conditions under which they may be utilised as part of a renewable electrochemical system. Benefits of this research should emerge in energy efficient technologies for generating fuels (formic acid) from waste products (carbon dioxide).Read moreRead less
Understanding novel electronic and magnetic states in 4d and 5d oxides. This project aims to investigate the correlation between structural and electronic drivers of behaviour in complex metal oxides. Transition metal oxides are critical for modern electronics and discovering new materials and determining their physical properties is essential for the introduction of new technologies. This project will synthesis and characterise thermally novel oxides containing 4d and 5d transition metals to es ....Understanding novel electronic and magnetic states in 4d and 5d oxides. This project aims to investigate the correlation between structural and electronic drivers of behaviour in complex metal oxides. Transition metal oxides are critical for modern electronics and discovering new materials and determining their physical properties is essential for the introduction of new technologies. This project will synthesis and characterise thermally novel oxides containing 4d and 5d transition metals to establish the relationships between the chemistry, crystal structure and physical properties of such oxides. The unusual hierarchy of interactions in such oxides, and high sensitivity to crystal fields and subtle structural distortions, makes such oxides candidate materials for the realisation of various emergent quantum phases that may be used in the next generation of electronics. The proposal has the potential to significantly advance Australian research and development capacity in advanced materials and the associated high-tech industries.Read moreRead less
Unlocking the potential of multiphoton photoredox catalysis. Photoredox catalysis promises sustainable alternatives to synthesise high-value chemicals using energy converted from visible light. The project aims to address the current lack of understanding about how these reactions operate at the molecular level, using innovative electrochemical and spectroscopic techniques. The expected outcomes include new catalytic systems containing multiple light-driven steps that provide reactivities beyond ....Unlocking the potential of multiphoton photoredox catalysis. Photoredox catalysis promises sustainable alternatives to synthesise high-value chemicals using energy converted from visible light. The project aims to address the current lack of understanding about how these reactions operate at the molecular level, using innovative electrochemical and spectroscopic techniques. The expected outcomes include new catalytic systems containing multiple light-driven steps that provide reactivities beyond those attainable in single-photon cycles. These will be applied to challenging modifications of large biomolecules under mild aqueous conditions. Anticipated benefits include adding value to Australia’s growing chemical industry through efficient green syntheses with reduced dependence on toxic solvents.Read moreRead less
Discovering New Chemistry and Potential Applications of Metal Tetrapyrroles. This project aims to make fundamental advances in inorganic chemistry, coordination chemistry and bioinorganic chemistry by preparing new metal-containing molecules based on specifically designed tetrapyrrole ligands. Innovative synthetic methods will be developed to enable systematic chemical modifications to explore the chemical and biological properties of the metal complexes. The potential of the new molecules to be ....Discovering New Chemistry and Potential Applications of Metal Tetrapyrroles. This project aims to make fundamental advances in inorganic chemistry, coordination chemistry and bioinorganic chemistry by preparing new metal-containing molecules based on specifically designed tetrapyrrole ligands. Innovative synthetic methods will be developed to enable systematic chemical modifications to explore the chemical and biological properties of the metal complexes. The potential of the new molecules to be of use as tracers for molecular imaging will be investigated. An expected outcome of this research will be an increased understanding of how chemical properties dictate the biological activity of metal complexes informing the potential long-term translation of this chemistry to to new molecular diagnostics and therapeutics.Read moreRead less
Earth Abundant Metal Complexes for Nitrogen Activation. This project aims to develop a range of complexes based around earth abundant metals that are capable of activating nitrogen (N2) at ambient pressure and temperature. The project expects to generate new knowledge in the area of organometallic chemistry, specifically with regards to molecular metal-metal bonding and subsequent reactivity towards the activation of nitrogen. The activation of atmospheric nitrogen is performed on a multi-millio ....Earth Abundant Metal Complexes for Nitrogen Activation. This project aims to develop a range of complexes based around earth abundant metals that are capable of activating nitrogen (N2) at ambient pressure and temperature. The project expects to generate new knowledge in the area of organometallic chemistry, specifically with regards to molecular metal-metal bonding and subsequent reactivity towards the activation of nitrogen. The activation of atmospheric nitrogen is performed on a multi-million tonne scale each year and is key to a number of industrial processes. As such, investigations into new and improved catalysts for this process would potentially bring huge financial benefits to industry, as well as benefiting the environment by reducing energy demand and associated climate change.Read moreRead less
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