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New Horizons in Diels-Alder Chemistry. Using a unique joint experimental-computational approach, we will develop reliable ways to predict the outcome of one of the most important chemical reactions. Practical applications of these new predictive tools will be developed involving powerful new versions of the reaction. Several different classes of biologically active natural products will be prepared including molecules with antitumor and antiretroviral activities. Libraries of structurally-relate ....New Horizons in Diels-Alder Chemistry. Using a unique joint experimental-computational approach, we will develop reliable ways to predict the outcome of one of the most important chemical reactions. Practical applications of these new predictive tools will be developed involving powerful new versions of the reaction. Several different classes of biologically active natural products will be prepared including molecules with antitumor and antiretroviral activities. Libraries of structurally-related analogues of natural compounds will be synthesised for biological evaluation.Read moreRead less
The Baylis-Hillman Reaction: Asymmetric Organocatalysis and Applications. Many drugs come in two chiral mirror images (enantiomers) where the therapeutic effect is usually associated with only one while the other has no effect or can be harmful as was the case with thalidomide. Chemical reactions that yield just the desired mirror image, or enantiomer, and not the other are therefore in great demand and heavily pursued by the pharmaceutical, fine chemical and materials industries as a frontier ....The Baylis-Hillman Reaction: Asymmetric Organocatalysis and Applications. Many drugs come in two chiral mirror images (enantiomers) where the therapeutic effect is usually associated with only one while the other has no effect or can be harmful as was the case with thalidomide. Chemical reactions that yield just the desired mirror image, or enantiomer, and not the other are therefore in great demand and heavily pursued by the pharmaceutical, fine chemical and materials industries as a frontier technology. This project will result in the development of novel catalytic reactions that allow the synthesis of chiral chemicals in a cost-efficient and green manner needed by many industries, and also training of students with highly desirable synthetic skills to lead the next wave in pharmaceuticals and biotechnology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561203
Funder
Australian Research Council
Funding Amount
$110,000.00
Summary
Microwave Assisted Chemistry - new approaches to molecular diversity. This project will support the establishment of a multi-user, fully automated microwave reactor facility that will be the first of its kind in an academic laboratory in Australia. The equipment will support a wide range of synthetic chemistry research by providing microwave acceleration to otherwise slow reactions and in some cases promotion of reactions that do not normally proceed under conventional conditions. The automation ....Microwave Assisted Chemistry - new approaches to molecular diversity. This project will support the establishment of a multi-user, fully automated microwave reactor facility that will be the first of its kind in an academic laboratory in Australia. The equipment will support a wide range of synthetic chemistry research by providing microwave acceleration to otherwise slow reactions and in some cases promotion of reactions that do not normally proceed under conventional conditions. The automation capability will be used to create diverse compound libraries and to investigate and optimise reaction conditions.Read moreRead less
New photoinitiators and polymers for tack-free LED cured surface coatings. This project aims to develop surface coatings curable by energy from Light Emitting Diodes (LEDS) by overcoming existing hurdles, while improving workplace health and safety.
The project expects to achieve this by developing a new class of photoinitiator molecules, with enhanced reactivity, via a unique understanding of synthesis, photochemistry and commercial coatings formulation.
Outcomes will be new surface coatings ....New photoinitiators and polymers for tack-free LED cured surface coatings. This project aims to develop surface coatings curable by energy from Light Emitting Diodes (LEDS) by overcoming existing hurdles, while improving workplace health and safety.
The project expects to achieve this by developing a new class of photoinitiator molecules, with enhanced reactivity, via a unique understanding of synthesis, photochemistry and commercial coatings formulation.
Outcomes will be new surface coatings for a wide range of end uses, publication in high ranking journals and commercialisation of the technology.
Benefits of this project will include elimination of mercury and reduction in exposure to solvents in the Australian workplace, and a lower energy requirement to produce high-quality surface coated products.Read moreRead less
Getting the reaction outcomes you want: towards solvent-controlled reactivity using ionic liquids. Ionic liquids can replace existing reaction solvents, which may be volatile, flammable and toxic. However, the effect on the reaction outcome of such a replacement is poorly understood. This project aims to identify cases where ionic liquids will benefit a reaction, resulting in the development of improved processes.
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
Natural Product-derived Proteomics Probes for Specific Detection of Protein Kinase C Activities. Better health care depends on how well diseases are understood and how accurately disease analysis and diagnosis can be carried out. This is not only important to disease treatment but also prevention. This project will first generate new compounds that could have improved therapeutic value in cancer treatment. In addition, these compounds will be further engineered to provide a new technology of ....Natural Product-derived Proteomics Probes for Specific Detection of Protein Kinase C Activities. Better health care depends on how well diseases are understood and how accurately disease analysis and diagnosis can be carried out. This is not only important to disease treatment but also prevention. This project will first generate new compounds that could have improved therapeutic value in cancer treatment. In addition, these compounds will be further engineered to provide a new technology of tracing the molecular signature of diseases such as cancer for early detection and better preventative care and treatment. This will create new economic advantage and contributes to the transformation of Australian health care industry.Read moreRead less
Novel Synthetic Receptors for Recognition and Transport of Biologically Important Anions. Anion receptors are not currently tailored for the ‘real world’ biological environments (for example, physiological saline and membranes) in which anions perform their many critical roles. The project will design and synthesise a range of molecular receptors based on large, rigid, precisely functionalisable scaffolds, tailored specifically to complement both the shape, size and charge of target anions as we ....Novel Synthetic Receptors for Recognition and Transport of Biologically Important Anions. Anion receptors are not currently tailored for the ‘real world’ biological environments (for example, physiological saline and membranes) in which anions perform their many critical roles. The project will design and synthesise a range of molecular receptors based on large, rigid, precisely functionalisable scaffolds, tailored specifically to complement both the shape, size and charge of target anions as well as their native environment. The project will investigate the ability of these receptors to strongly bind their target anions with high selectivity in both aqueous systems and in membrane environments. This will lead to the development of innovative synthetic receptors that recognise and/or transport biological anions for use in biomedical applications.Read moreRead less
Tailored porphyrins for nanoscience applications. Porphyrins are the pigments of life, the central components of haemoglobin in blood and chlorophyll in living plants. In order to expand their use into important areas of nanoscience, this project will establish a new porphyrin paradigm. It will result in the synthesis of novel porphyrins with inbuilt structural features that enhance their propensity to self-assemble into monolayers on surfaces, and into nanorods. This will lead to advanced mate ....Tailored porphyrins for nanoscience applications. Porphyrins are the pigments of life, the central components of haemoglobin in blood and chlorophyll in living plants. In order to expand their use into important areas of nanoscience, this project will establish a new porphyrin paradigm. It will result in the synthesis of novel porphyrins with inbuilt structural features that enhance their propensity to self-assemble into monolayers on surfaces, and into nanorods. This will lead to advanced materials for molecular sensing, photonics, molecular memory devices, catalysis, and organic photovoltaics. A new means of improving the efficiency of solar cells will also be explored. Well-trained graduates and strong international scientific cooperation will also result from the project.Read moreRead less