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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100049
Funder
Australian Research Council
Funding Amount
$270,000.00
Summary
Nuclear Magnetic Resonance facility for Northern Australia. Nuclear magnetic resonance facility for Northern Australia: Nuclear magnetic resonance spectroscopy is a fundamentally and critically important technique in the characterisation of organic, inorganic and biological compounds. Research areas that will be supported by this facility include organometallic chemistry and the development of new materials and analytical sensors; organic photochemistry as applied in synthesis and degradation; a ....Nuclear Magnetic Resonance facility for Northern Australia. Nuclear magnetic resonance facility for Northern Australia: Nuclear magnetic resonance spectroscopy is a fundamentally and critically important technique in the characterisation of organic, inorganic and biological compounds. Research areas that will be supported by this facility include organometallic chemistry and the development of new materials and analytical sensors; organic photochemistry as applied in synthesis and degradation; and natural products, pharmaceutical, and inorganic chemistry, where multinuclear nuclear magnetic resonance is most important and applicable in drug design, development and delivery.Read moreRead less
Biomimetic Synthesis of Dimeric Natural Products. The aim of this research is to use nature as a source of inspiration and direction to improve and develop synthetic organic chemistry. Through targeted total syntheses this project will investigate and learn about the highly sophisticated way nature utilises dimerizations to rapidly generate molecular complexity. This project will demonstrate the power of this biomimetic strategy by synthesising a wide variety of complex dimeric natural products ....Biomimetic Synthesis of Dimeric Natural Products. The aim of this research is to use nature as a source of inspiration and direction to improve and develop synthetic organic chemistry. Through targeted total syntheses this project will investigate and learn about the highly sophisticated way nature utilises dimerizations to rapidly generate molecular complexity. This project will demonstrate the power of this biomimetic strategy by synthesising a wide variety of complex dimeric natural products including phenylethanoids, alkaloids, lignans, terpenes and coumarins. The expected outcome will be uniquely efficient synthetic strategies that significantly surpass all previous approaches and new synthetic methodology that will be of broad use in organic synthesis.Read moreRead less
Using natural products to inspire discoveries in synthesis and biosynthesis. This project aims to understand the organic chemistry that occurs in the biosynthesis of unusual antibiotic natural products by marine microorganisms. In an interdisciplinary approach, proposed biosynthetic intermediates will be synthesised and screened against newly isolated enzymes from the microorganisms of interest. This will allow the elucidation of biosynthetic pathways, and aid the discovery of new chemoenzymatic ....Using natural products to inspire discoveries in synthesis and biosynthesis. This project aims to understand the organic chemistry that occurs in the biosynthesis of unusual antibiotic natural products by marine microorganisms. In an interdisciplinary approach, proposed biosynthetic intermediates will be synthesised and screened against newly isolated enzymes from the microorganisms of interest. This will allow the elucidation of biosynthetic pathways, and aid the discovery of new chemoenzymatic reactivity that may be broadly useful in organic synthesis. Non-enzymatic, predisposed organic reactions will also be uncovered during the project. The benefit of this project will be an improvement in our ability to synthesise potential antibiotics using a combined synthetic organic and chemoenzymatic approach. This could lead to useful new antibiotics in the future.Read moreRead less
Extending the frontiers of organocatalysis: new reactions involving nucleophilic carbenes. High technology solutions to the problems of today and tomorrow require new materials designed for specific activities. This project will deliver new technologies for the rapid and efficient assembly of materials designed for function.
Challenges to organocatalysis. This project aims to use organocatalysis to generate organocatalytic C=C insertion, C-H functionalisation and carbonyl ylide/1,3-dipolar cycloaddition reactions. Organocatalysis has transformed the way chemical synthesis is performed. However, in the early years the focus of this discipline has primarily been enolate type chemistry, and more challenging reactions, such as those involving carbenoid intermediates, have not been contemplated. Previously such reactions ....Challenges to organocatalysis. This project aims to use organocatalysis to generate organocatalytic C=C insertion, C-H functionalisation and carbonyl ylide/1,3-dipolar cycloaddition reactions. Organocatalysis has transformed the way chemical synthesis is performed. However, in the early years the focus of this discipline has primarily been enolate type chemistry, and more challenging reactions, such as those involving carbenoid intermediates, have not been contemplated. Previously such reactions have only been achieved using transition metal catalysts. This project addresses this limitation, allowing the strengths of organocatalysis (abundance and diversity, access to enantiopurity, elemental sustainability) to affect the broader landscape of catalysis. This approach could present an opportunity to examine reactivity patterns, stereoselectivity and cascade design and may lead to new reaction technologies.Read moreRead less
New Reaction Cascades Exploiting N-Heterocyclic Carbenes. Catalytic reactions can enhance the efficiency of chemical synthesis, decreasing environmental and financial cost. This project will undertake the discovery and development of reactions in which a catalyst enables a "production line" of events to provide complex and valuable products. These reactions will proceed with high shape selectivity (enantioselectivity). In addition to new chemical transformations the output of these studies inclu ....New Reaction Cascades Exploiting N-Heterocyclic Carbenes. Catalytic reactions can enhance the efficiency of chemical synthesis, decreasing environmental and financial cost. This project will undertake the discovery and development of reactions in which a catalyst enables a "production line" of events to provide complex and valuable products. These reactions will proceed with high shape selectivity (enantioselectivity). In addition to new chemical transformations the output of these studies includes intellectual capital and human resources, all of which are integral to sustaining a strong chemical manufacturing sector.Read moreRead less
Ring-Strain Relief: Applications in Total Synthesis. This proposal aims to investigate the chemical synthesis of a number of structurally different natural product target molecules by strategies involving the use of either three or four membered ring-strained compounds to afford key synthetic intermediates in an efficient manner. The key aim of this research is to provide more efficient routes to complex natural products and analogues. The research strives to be at the forefront of modern synthe ....Ring-Strain Relief: Applications in Total Synthesis. This proposal aims to investigate the chemical synthesis of a number of structurally different natural product target molecules by strategies involving the use of either three or four membered ring-strained compounds to afford key synthetic intermediates in an efficient manner. The key aim of this research is to provide more efficient routes to complex natural products and analogues. The research strives to be at the forefront of modern synthetic organic chemistry and aims to contribute to the Science of complex molecule synthesis.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.