Sustainable Reversible Polymerisation. This project aims to address the problem of the current lack of efficient chemical recyclability of polymers. For the majority of polymers, no methods exist so far that are scalable and economic at the same time. To reach this aim, we will utilise a mixture of clever chemical concepts with continuous flow engineering. This project expects to generate new knowledge in the area of depolymerisation and chemical recycling methods. The expected outcome of this p ....Sustainable Reversible Polymerisation. This project aims to address the problem of the current lack of efficient chemical recyclability of polymers. For the majority of polymers, no methods exist so far that are scalable and economic at the same time. To reach this aim, we will utilise a mixture of clever chemical concepts with continuous flow engineering. This project expects to generate new knowledge in the area of depolymerisation and chemical recycling methods. The expected outcome of this project is a scalable process and its practical demonstration for full chemical recycling of various polymers used in everyday applications. This will provide a benefit to society as it allows to tackle plastic pollution problems, and creates avenues to green methods in plastic recycling.
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Discovery Early Career Researcher Award - Grant ID: DE230100138
Funder
Australian Research Council
Funding Amount
$419,804.00
Summary
Developing Switchable Ligands to Control Gold Nanocluster Interfaces. This project aims to unlock the promising catalytic activity of protected gold nanoclusters by developing switchable ligands capable of undergoing controlled detachment and exchange. This project expects to provide a detailed understanding of how the gold thiolate interface of nanoclusters influences their physical and chemical properties. Expected outcomes include the design of improved catalysts for chemical synthesis and bi ....Developing Switchable Ligands to Control Gold Nanocluster Interfaces. This project aims to unlock the promising catalytic activity of protected gold nanoclusters by developing switchable ligands capable of undergoing controlled detachment and exchange. This project expects to provide a detailed understanding of how the gold thiolate interface of nanoclusters influences their physical and chemical properties. Expected outcomes include the design of improved catalysts for chemical synthesis and biological assays using computer aided chemical modelling. These catalysts should be easier to recover after use, which should improve cost-effectiveness. They should also improve the accuracy of biological sensors, which could ultimately be used for the rapid and early detection of diseases.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100147
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
Revitalising NMR facilities in South Australia - Stage 2. The determination of molecular structure using Nuclear Magnetic Resonance (NMR) is a fundamental and powerful technique that is utilised by researchers across numerous disciplines. We are proposing to upgrade NMR facilities within South Australia in a carefully staged process so as to provide researchers access to state of the art experiments on modern instrumentation. In this proposal we aim to replace end of life components as well as p ....Revitalising NMR facilities in South Australia - Stage 2. The determination of molecular structure using Nuclear Magnetic Resonance (NMR) is a fundamental and powerful technique that is utilised by researchers across numerous disciplines. We are proposing to upgrade NMR facilities within South Australia in a carefully staged process so as to provide researchers access to state of the art experiments on modern instrumentation. In this proposal we aim to replace end of life components as well as provide increased sensitivity and capability by installing new probes. We aim to minimise duplication and maximise capability by undertaking a coordinated approach to NMR upgrades.Read moreRead less
New Horizons in Quinonedimethide Chemistry. Quinonedimethides (QDMs) are organic molecules with a notorious reputation for instability, hence they are poorly understood and an underexploited resource. This project will unite the ideally suited computational and experimental skills of the CIs to perform the first thorough investigation into fundamental QDM chemistry. It aims to map structure-reactivity in QDMs, investigate their ability to rapidly generate complex structures, and demonstrate thei ....New Horizons in Quinonedimethide Chemistry. Quinonedimethides (QDMs) are organic molecules with a notorious reputation for instability, hence they are poorly understood and an underexploited resource. This project will unite the ideally suited computational and experimental skills of the CIs to perform the first thorough investigation into fundamental QDM chemistry. It aims to map structure-reactivity in QDMs, investigate their ability to rapidly generate complex structures, and demonstrate their potential in spintronics and other applications. Anticipated outcomes include powerful and general new synthetic concepts, methods, strategies and tactics. This should provide significant benefits, such as better ways to manufacture important medicines and other materials.Read moreRead less
How are plants responding to damage by oxidizing air pollutants? This project aims to obtain detailed understanding of the chemical processes by which the air pollutants ozone and nitrogen dioxide damage plants. Through an interdisciplinary approach involving physical organic chemistry and analytical biochemistry, this project intends to discover important reactions between plant biomolecules and air pollutants, identify biochemical mechanisms for pollution damage in crop model plants and reveal ....How are plants responding to damage by oxidizing air pollutants? This project aims to obtain detailed understanding of the chemical processes by which the air pollutants ozone and nitrogen dioxide damage plants. Through an interdisciplinary approach involving physical organic chemistry and analytical biochemistry, this project intends to discover important reactions between plant biomolecules and air pollutants, identify biochemical mechanisms for pollution damage in crop model plants and reveal the plant defence mechanism at the molecular level. Expected outcomes include the much-needed scientific foundations to support the development of more pollution-resilient crops in the future, ultimately enabling a breakthrough for the triple challenge of environmental pollution, climate change and food security.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100664
Funder
Australian Research Council
Funding Amount
$451,847.00
Summary
Pushing the limits of electronic delocalization in organic molecules. This project aims to uncover the factors which control how molecules delocalize electrons in 1, 2, and 3 dimensions. Electronic delocalization is essential for many applications of molecular materials, such as light-harvesting and energy storage, but it remains poorly understood. The expected outcomes of this project include new highly-conductive molecules, transferrable knowledge about aromaticity, and design principles for f ....Pushing the limits of electronic delocalization in organic molecules. This project aims to uncover the factors which control how molecules delocalize electrons in 1, 2, and 3 dimensions. Electronic delocalization is essential for many applications of molecular materials, such as light-harvesting and energy storage, but it remains poorly understood. The expected outcomes of this project include new highly-conductive molecules, transferrable knowledge about aromaticity, and design principles for future organic materials. The expected benefits flow from the foundational nature of this research: pi-conjugated organic molecules have many potential uses, including: sensors (e.g. for environmental monitoring), solar cells, and OLED screens, and this project is expected to improve these technologies and industries.Read moreRead less