Fighting slime with free radicals - new surface coatings for biofilm remediation. Bacterial biofilms are a major problem in a number of environmental, industrial and medical applications. They cause significant risks to human health and present an enormous economic burden to society. This project aims to develop smart polymeric coatings that will discourage bacterial attachment and ensure greater long term control over biofilm growth. These coatings represent a breakthrough in the field and will ....Fighting slime with free radicals - new surface coatings for biofilm remediation. Bacterial biofilms are a major problem in a number of environmental, industrial and medical applications. They cause significant risks to human health and present an enormous economic burden to society. This project aims to develop smart polymeric coatings that will discourage bacterial attachment and ensure greater long term control over biofilm growth. These coatings represent a breakthrough in the field and will have a profound impact in many areas, including reducing infections related to medical implants and improving the efficiency of marine engineering systems.Read moreRead less
High performance chromatography based on nanostructured monolithic polymers. The proposed project will generate highly significant, fundamental advances in separation science by developing new stationary phases and separation technologies suitable for the analysis of very complex samples which cannot be addressed by current methods. These technologies will be applied in a wide range of areas of national importance including pharmaceutical analysis and drug discovery; environmental, clinical, and ....High performance chromatography based on nanostructured monolithic polymers. The proposed project will generate highly significant, fundamental advances in separation science by developing new stationary phases and separation technologies suitable for the analysis of very complex samples which cannot be addressed by current methods. These technologies will be applied in a wide range of areas of national importance including pharmaceutical analysis and drug discovery; environmental, clinical, and forensic analysis; energy generation and foods. The project will also lead to very significant new intellectual property having extremely high commercial potential worldwide, and thereby generates the promise of considerable direct financial returns to Australia.Read moreRead less
Novel organic architectures and functional materials from tropylium ions. This project aims to develop new synthetic applications of tropylium ions, as versatile building blocks, to access a broad range of organic structures that used to be difficult and problematic to synthesise. The non-benzenoid aromatic tropylium ion exhibits a unique combination of structural stability and chemical reactivity. This project expects to use tropylium ions as chromophores to derive novel ‘push-and-pull’ organic ....Novel organic architectures and functional materials from tropylium ions. This project aims to develop new synthetic applications of tropylium ions, as versatile building blocks, to access a broad range of organic structures that used to be difficult and problematic to synthesise. The non-benzenoid aromatic tropylium ion exhibits a unique combination of structural stability and chemical reactivity. This project expects to use tropylium ions as chromophores to derive novel ‘push-and-pull’ organic dyes with highly applicable physicochemical properties.This will provide access to a family of novel complex organic structures in a new chemical space, as well as new materials for opto-electronic and sensing applications, respectively.Read moreRead less
Next Generation Photocatalysis for Chemical Synthesis and Manufacture. This project aims to discover new methods for the activation of energy demanding bonds in organic molecules as a general strategy in chemical synthesis. A key conceptual advance in this project is the development of multiphoton photoredox catalysis as a powerful tool to activate traditionally unreactive, yet abundant chemical bonds in organic molecules including C-H bonds in alkane and olefin feedstocks. With application in f ....Next Generation Photocatalysis for Chemical Synthesis and Manufacture. This project aims to discover new methods for the activation of energy demanding bonds in organic molecules as a general strategy in chemical synthesis. A key conceptual advance in this project is the development of multiphoton photoredox catalysis as a powerful tool to activate traditionally unreactive, yet abundant chemical bonds in organic molecules including C-H bonds in alkane and olefin feedstocks. With application in fields that range from fine chemical production to drug discovery, the overarching aim of this research is to establish new bond activation reactions and to demonstrate translations to the invention of new pharmaceuticals, agrochemicals and advanced chemical manufacturing processes that will have societal impact.Read moreRead less
Harnessing light and electricity to drive chemical synthesis. This project will explore and establish original strategies that use inputs of energy (light and electricity) to break or form chemical bonds, which can provide new or improved access to valuable compounds. In this way, this research will augment or enhance existing methods for the selective and direct manipulation of molecules by creating tools that allow chemists to prepare molecules under particularly mild conditions. The outcomes ....Harnessing light and electricity to drive chemical synthesis. This project will explore and establish original strategies that use inputs of energy (light and electricity) to break or form chemical bonds, which can provide new or improved access to valuable compounds. In this way, this research will augment or enhance existing methods for the selective and direct manipulation of molecules by creating tools that allow chemists to prepare molecules under particularly mild conditions. The outcomes of the project will include the development of new technology for organic synthesis and forging novel approaches for chemical alkylation and cross-coupling reactions. This can contribute to making important compounds more efficiently, safely and cheaper to produce in the future.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
Internally decorated discrete Metallo-supramolecular Assemblies and infinite Metal-Organic Frameworks as molecular containers. In the macroscopic world, containers are used to hold, provide physical protection, or create a modified environment for their contents. This project will result in the synthesis of novel molecular container materials that provide decorated internal surfaces capable of selectively binding chemical species. In addition to the breakthrough scientific benefits of establish ....Internally decorated discrete Metallo-supramolecular Assemblies and infinite Metal-Organic Frameworks as molecular containers. In the macroscopic world, containers are used to hold, provide physical protection, or create a modified environment for their contents. This project will result in the synthesis of novel molecular container materials that provide decorated internal surfaces capable of selectively binding chemical species. In addition to the breakthrough scientific benefits of establishing the fundamentals of these systems, the binding of chemicals, which are environmental contaminants, will provide the grounding for applications that will contribute to the national priority of 'Frontier technologies'. Furthermore, this research will lead to the training of the next generation of Australian scientists by quality international researchers.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.
New Chiral Metal Catalysts; Going Beyond the State of the Art. The synthesis of both natural and unnatural organic compounds in optically active form is a central challenge in chemistry. Because the most important molecules in nature are chiral and of specific handedness, there exists a growing need to access any given organic compound in its optically pure form. Asymmetric catalysis offers the most elegant way to solving this problem and this project will target some of the difficult challenges ....New Chiral Metal Catalysts; Going Beyond the State of the Art. The synthesis of both natural and unnatural organic compounds in optically active form is a central challenge in chemistry. Because the most important molecules in nature are chiral and of specific handedness, there exists a growing need to access any given organic compound in its optically pure form. Asymmetric catalysis offers the most elegant way to solving this problem and this project will target some of the difficult challenges in realising asymmetric synthesis, building new, privileged chiral ligands, opening new catalytic pathways for constructing chiral compounds and understanding the intimate catalytic pathway that enables reactivity and selectivity. This will generate applications across the chemical industries.Read moreRead less
Discovering new organic chemistry using an inorganic touch. This project aims to discover new organic chemistry by treating carbon like a metal atom. Advances in fundamental organic chemistry have been important in developing products, including medicines, plastics and television display technology. Much research activity relies on applying existing organic chemistry, but inventing genuinely new organic chemistry is more difficult. By viewing carbon as a metal, this project will try to solve imp ....Discovering new organic chemistry using an inorganic touch. This project aims to discover new organic chemistry by treating carbon like a metal atom. Advances in fundamental organic chemistry have been important in developing products, including medicines, plastics and television display technology. Much research activity relies on applying existing organic chemistry, but inventing genuinely new organic chemistry is more difficult. By viewing carbon as a metal, this project will try to solve important problems in organic chemistry that have been unresolved for decades, and synthesise valuable chemicals normally generated using expensive precious metal catalysts.Read moreRead less