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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
Discovery Early Career Researcher Award - Grant ID: DE210100065
Funder
Australian Research Council
Funding Amount
$423,808.00
Summary
Designing Organocatalysts to Achieve Hyperpolarised Magnetic Resonance. Magnetic resonance techniques (such as MRI scans) suffer from an inherent insensitivity problem. In medical imaging, this can hamper diagnosis and mean long scan times for patients. This project aims to chemically develop catalysts which dramatically increase sensitivity, producing a signal that is thousands of times more visible. This project is significant as these catalysts can turn common, harmless molecules in the body ....Designing Organocatalysts to Achieve Hyperpolarised Magnetic Resonance. Magnetic resonance techniques (such as MRI scans) suffer from an inherent insensitivity problem. In medical imaging, this can hamper diagnosis and mean long scan times for patients. This project aims to chemically develop catalysts which dramatically increase sensitivity, producing a signal that is thousands of times more visible. This project is significant as these catalysts can turn common, harmless molecules in the body - even water - into visible tracers. The expected outcomes of this project include the synthesis and understanding of these catalysts which will be chemically fine-tuned to maximise their effectiveness. Potential benefits include translation to MRI applications to improve diagnosis and treatment, or chemical monitoring.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100053
Funder
Australian Research Council
Funding Amount
$428,710.00
Summary
Computational Discovery & Design of New Catalytic Halogenophilic Reactions. Computational chemistry will be used to discover and predict new halogenophilic (halogeno = halogen; philic = like) substitution reactions (SN2X) catalysed by positively charged (cationic) catalysts. SN2X is a less known substitution reaction compared to accepted textbook nucleophilic (nucleo = electron-rich) substitution reactions. This proposal capitalises on previous theoretical-experimental understanding of a cation- ....Computational Discovery & Design of New Catalytic Halogenophilic Reactions. Computational chemistry will be used to discover and predict new halogenophilic (halogeno = halogen; philic = like) substitution reactions (SN2X) catalysed by positively charged (cationic) catalysts. SN2X is a less known substitution reaction compared to accepted textbook nucleophilic (nucleo = electron-rich) substitution reactions. This proposal capitalises on previous theoretical-experimental understanding of a cation-catalysed SN2X to develop new chemical reactions using SN2X synthetic strategies to access difficult-to-make molecules of potential medicinal relevance with heavily substituted carbon-carbon and carbon heteroatom bonds. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100513
Funder
Australian Research Council
Funding Amount
$374,000.00
Summary
Advancing flow chemistry: towards total flow synthesis. Of all mankind's endeavors, the development and mass production of pharmaceuticals is arguably the most resource hungry and wasteful. This project aims to advance a branch of chemistry known as flow chemistry. This emerging technology has the potential to revolutionise pharmaceutical production by improving quality and reducing chemical waste.
Discovery Early Career Researcher Award - Grant ID: DE170100677
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Deconstructing molecular self-assembly by advanced mass spectrometry. This project aims to develop ion-mobility mass spectrometry methods to observe the molecular evolution of model self-assembly reactions with high temporal and structural resolution, and interrogate the intrinsic gas phase functionality of the assemblies themselves, including aggregation, inclusion and disassembly behaviours. Lack of knowledge of reaction intermediates, mechanisms and kinetics hampers the industrial potential o ....Deconstructing molecular self-assembly by advanced mass spectrometry. This project aims to develop ion-mobility mass spectrometry methods to observe the molecular evolution of model self-assembly reactions with high temporal and structural resolution, and interrogate the intrinsic gas phase functionality of the assemblies themselves, including aggregation, inclusion and disassembly behaviours. Lack of knowledge of reaction intermediates, mechanisms and kinetics hampers the industrial potential of self-assembly to fabricate highly functional materials. This project expects to determine the critical link between the assemblies’ structure and function, and provide the rational framework to optimise and direct synthetic outcomes. This could enable Australian manufacturers to create low-energy production processes of high value commodities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100462
Funder
Australian Research Council
Funding Amount
$364,975.00
Summary
Molecular complexity through multi-bond forming reactions. This project aims to develop techniques for the synthesis of many, highly valuable natural and designed molecules which are too complex to be synthesised on scale with current methodologies. The project aims to develop new strategies for the simultaneous construction of several chemical bonds, with a focus on molecular scaffolds that can be readily converted into pharmaceuticals, potential drug candidates, chiral ligands, and agrochemica ....Molecular complexity through multi-bond forming reactions. This project aims to develop techniques for the synthesis of many, highly valuable natural and designed molecules which are too complex to be synthesised on scale with current methodologies. The project aims to develop new strategies for the simultaneous construction of several chemical bonds, with a focus on molecular scaffolds that can be readily converted into pharmaceuticals, potential drug candidates, chiral ligands, and agrochemicals. This will ultimately lead to advancements in both the production and application of organic molecules in these fields.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100689
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Applying nature's chemistry to the synthesis of complex bioactive natural products. Organic molecules come in all shapes and sizes, and the synthesis of them is crucial to industries as diverse as pharmaceuticals, electronics, cosmetics and agrochemicals. This project aims to develop new ways of making unusual and potentially useful naturally occurring organic molecules using chemistry that mimics how they are formed in nature.
Discovery Early Career Researcher Award - Grant ID: DE120102113
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Total synthesis inspired by nature. This project aims to improve and develop the way in which we make organic substances; our medicines, agrochemicals, and designed materials. This will be achieved through biomimetics; which harnesses the power of evolution by mimicking how nature synthesises organic compounds.
Discovery Early Career Researcher Award - Grant ID: DE160101548
Funder
Australian Research Council
Funding Amount
$373,052.00
Summary
Enantioselective catalysis using P-chiral phosphines and phosphinamines. This project aims to develop new methods to synthesise organic molecules. The synthesis of organic molecules for medicines, polymers and other applications depends on the use of catalysts to promote chemical reactions. The use of small organic catalysts, rather than those based on transition metals or enzymes, offers many advantages in the form of low toxicity, low cost, ease of use and minimal environmental impact. This pr ....Enantioselective catalysis using P-chiral phosphines and phosphinamines. This project aims to develop new methods to synthesise organic molecules. The synthesis of organic molecules for medicines, polymers and other applications depends on the use of catalysts to promote chemical reactions. The use of small organic catalysts, rather than those based on transition metals or enzymes, offers many advantages in the form of low toxicity, low cost, ease of use and minimal environmental impact. This project aims to deliver new methods for synthesis using new approaches in organocatalysis. The methods will be used to synthesise important molecules, including novel catalysts, biocompatible polyester materials and chiral phosphines, which are widely used in chemical industry but difficult and expensive to produce.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100186
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Base stabilised dicarbon as a new building block for supramolecular organometallic chemistry. Diamond, coal and graphite are the forms of carbon ("allotropes") found in everyday life. The discovery of two further allotropes of carbon, the fullerenes and graphene both led to Nobel Prize awards. We have identified a method to stabilize another form of carbon, dicarbon, and will harness its properties for the formation of new materials.