Multiblock copolymer synthesis for nano-engineered materials. This project aims to develop methodology for environmentally friendly and industrially applicable synthesis of new types of advanced polymeric materials comprising multiblock copolymers. Polymeric materials play an important role in society with applications from bulk plastics to advanced technological applications. This would enable the creation of advanced materials with specific engineering targets and applications ranging from nan ....Multiblock copolymer synthesis for nano-engineered materials. This project aims to develop methodology for environmentally friendly and industrially applicable synthesis of new types of advanced polymeric materials comprising multiblock copolymers. Polymeric materials play an important role in society with applications from bulk plastics to advanced technological applications. This would enable the creation of advanced materials with specific engineering targets and applications ranging from nanomedicine to materials science.Read moreRead less
Polymerization Mechanism and Kinetics of 1,1-Disubstituted Monomers. This project focuses on two exciting research areas: (I) we have found that an oxygen atom b to the double bond activates radical polymerization, making a whole new family of polymeric structures accessible, and (II) we have strong preliminary data that demonstrates a very large solvent effect on propagation and termination reactions for acrylic monomers with an a-CH2OH functionality, suggesting that significant control can be ....Polymerization Mechanism and Kinetics of 1,1-Disubstituted Monomers. This project focuses on two exciting research areas: (I) we have found that an oxygen atom b to the double bond activates radical polymerization, making a whole new family of polymeric structures accessible, and (II) we have strong preliminary data that demonstrates a very large solvent effect on propagation and termination reactions for acrylic monomers with an a-CH2OH functionality, suggesting that significant control can be exerted over the polymerization process using additives. Additionally, we demonstrate that polymers containing repeat units with an a-CH2OH functionality can undergo reversible cyclization, enabling a whole range of novel functional materials.Read moreRead less
Mechanisms in Catalytic Chain Transfer Polymerization. The aim of the proposed research is to gain more insight into the mechanisms underlying catalytic chain transfer polymerization, a relatively recent controlled radical polymerization technique which is finding an increasing number of industrial applications, especially in the paint and coatings industry. An improved understanding of the catalytic chain transfer process, of which some very important features are still poorly understood, will ....Mechanisms in Catalytic Chain Transfer Polymerization. The aim of the proposed research is to gain more insight into the mechanisms underlying catalytic chain transfer polymerization, a relatively recent controlled radical polymerization technique which is finding an increasing number of industrial applications, especially in the paint and coatings industry. An improved understanding of the catalytic chain transfer process, of which some very important features are still poorly understood, will ultimately lead to better catalyst design and improved process and product control. This in turn will lead to novel polymeric materials.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL200100124
Funder
Australian Research Council
Funding Amount
$3,372,617.00
Summary
Very small nanoparticles made to measure. The administration of therapeutic drugs is often unsuccessful as the drug is quickly cleared from the body. Nanoparticles have been shown to enhance the efficiency of the drug administration, as evidenced by the increasing number of nanoformulations on the market, although commercially available products have currently a range of shortcomings, some of them related to their size. This research program aims to develop a toolset that allows the design of ve ....Very small nanoparticles made to measure. The administration of therapeutic drugs is often unsuccessful as the drug is quickly cleared from the body. Nanoparticles have been shown to enhance the efficiency of the drug administration, as evidenced by the increasing number of nanoformulations on the market, although commercially available products have currently a range of shortcomings, some of them related to their size. This research program aims to develop a toolset that allows the design of very small nanoparticles that display enhanced biological activity. The outcome will be an in-depth understanding of the relationship between polymer structure and properties, which is not only important for nanomedicine, but other areas such as catalysis and sensors. Read moreRead less
Branching in acrylic polymers: analysis and mechanistic understanding. Some polymers can be branched. This branching has major effects on the end-product performance of a polymer, for example in adhesives and the flexibility of rubbery materials. Full quantification of this branching (the lengths of branches and the rates of the processes that create them) has been impossible hitherto. Two new complementary techniques, a new analytical method developed by the applicant Fellow in Paris, and a new ....Branching in acrylic polymers: analysis and mechanistic understanding. Some polymers can be branched. This branching has major effects on the end-product performance of a polymer, for example in adhesives and the flexibility of rubbery materials. Full quantification of this branching (the lengths of branches and the rates of the processes that create them) has been impossible hitherto. Two new complementary techniques, a new analytical method developed by the applicant Fellow in Paris, and a new synthesis technique developed in Sydney, will be used as the platforms to devise the first means of determining this information and thus understanding and quantifying branching.Read moreRead less
Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at ....Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at high costs. This project expects its new materials will increase manufacturing sustainability, chemical diversity and industrial viability; produce health benefits for Australia by improving chemotherapy and diagnosis for diseases; and benefit the Australian economy.Read moreRead less
Synthesis of nanocomposite polymers with targeted properties. This project aims to synthesise novel nanocomposite polymers by living radical polymerisation in water and to understand the way polymer microstructure and nanomorphology control material properties. This will provide the enabling science so that nanomaterials with targeted properties can be tailor-made for biomedical and speciality-coatings applications, and thus dispense with the current trial-and-error methodology. The innovations ....Synthesis of nanocomposite polymers with targeted properties. This project aims to synthesise novel nanocomposite polymers by living radical polymerisation in water and to understand the way polymer microstructure and nanomorphology control material properties. This will provide the enabling science so that nanomaterials with targeted properties can be tailor-made for biomedical and speciality-coatings applications, and thus dispense with the current trial-and-error methodology. The innovations in this project are the novel synthesis of complex polymer architectures in water, and the first quantitative and qualitative structure-property correlations for such materials. This will also result in a deepened understanding of the mechanisms governing the formation of these nanocomposites.Read moreRead less
New-generation starch-based paper coatings. This project is to make a new hybrid biomaterial which encapsulates starch in a synthetic polymer latex for use in paper manufacture. A novel process has been devised for this by the parties. This project is the fundamental research and development needed to turn successful preliminary experiments into commercial reality; it involves a unique combination of cereal and polymer scientists and paper technologists. The product has the potential to set up a ....New-generation starch-based paper coatings. This project is to make a new hybrid biomaterial which encapsulates starch in a synthetic polymer latex for use in paper manufacture. A novel process has been devised for this by the parties. This project is the fundamental research and development needed to turn successful preliminary experiments into commercial reality; it involves a unique combination of cereal and polymer scientists and paper technologists. The product has the potential to set up a new industry to use starch from Australian cereal grains to replace imports and create new markets, as well as reducing environmental problems from paper manufacture.Read moreRead less
Design of Polymeric Devices for Biotechnological Applications. The research project focuses on the development of functional polymer particles for diagnostic applications. Advanced polymer chemistry will be used to synthesize devices for reliable and fast diagnostic systems. The outcome of this work will help promoting and maintaining good health in Australia by developing novel technologies and advanced materials based on polymer science.
Novel barrier products: synthesis design using controlled radical polymerization in dispersed systems. Personal barrier products (eg surgical and industrial rubber gloves) are currently manufactured using emulsion polymerization synthesis methods that have evolved little in 50 years. A dramatic new method for controlling polymer architecture, developed by a team led by the CI and Dulux for paints, also has the potential to tailor-make barrier products, from less hazardous raw materials. This pro ....Novel barrier products: synthesis design using controlled radical polymerization in dispersed systems. Personal barrier products (eg surgical and industrial rubber gloves) are currently manufactured using emulsion polymerization synthesis methods that have evolved little in 50 years. A dramatic new method for controlling polymer architecture, developed by a team led by the CI and Dulux for paints, also has the potential to tailor-make barrier products, from less hazardous raw materials. This project commences the fundamental research for understanding the mechanisms involved in using this method with butadiene, and the mechanical properties of the resulting novel block copolymers. This science would later be applied by the industrial partner to significantly improve their barrier products.Read moreRead less