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
Highly functional green materials platform: Starch-ionic liquid-carbon nanotube polymer melt nanocomposites. This project will deliver state of the art scientific advances in green polymers, green plasticisers and tailored nanomaterials for melt processible renewable starch plastics for high-performance applications as electroactive polymers in areas such as biosensors and biodiagnostics.
Discovery Early Career Researcher Award - Grant ID: DE170101249
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Polymers with controllable networks. This project aims to understand the mechanism and molecular level factors controlling the network flexibility, reversibility and rapid curing of cross-linked polymer structures. A highly formable, rapidly curing polymer network could improve manufacture of composites where a fibre material is embedded in a polymer matrix. The key challenges for these materials are achieving high rates of production (one part per minute) and end of life recyclability. Expected ....Polymers with controllable networks. This project aims to understand the mechanism and molecular level factors controlling the network flexibility, reversibility and rapid curing of cross-linked polymer structures. A highly formable, rapidly curing polymer network could improve manufacture of composites where a fibre material is embedded in a polymer matrix. The key challenges for these materials are achieving high rates of production (one part per minute) and end of life recyclability. Expected outcomes are polymer materials with tailorable properties and the uptake of lightweight composite materials into mass transport systems.Read moreRead less
Biomimetic templating radical polymerisation in nanoreactors. The aim is to develop methodology for synthesis of polymer with hitherto inaccessible control of the microstructure by free radical means, that is the molecular weight distribution and monomer sequences. This will be achieved by combining the two concepts of biomimetic templated radical polymerisation and polymerisation in nanoreactors in the form of submicron-sized micelles or droplets. Scale-up of the methodology will be developed b ....Biomimetic templating radical polymerisation in nanoreactors. The aim is to develop methodology for synthesis of polymer with hitherto inaccessible control of the microstructure by free radical means, that is the molecular weight distribution and monomer sequences. This will be achieved by combining the two concepts of biomimetic templated radical polymerisation and polymerisation in nanoreactors in the form of submicron-sized micelles or droplets. Scale-up of the methodology will be developed based on an environmentally friendly approach whereby miniemulsions are generated using carbon dioxide. Increased ability to control the polymer microstructure will enable advanced design of functional polymers with far-reaching applications in materials science, nanotechnology and nanomedicine. Read moreRead less
Vesicles stabilised by compressed carbon dioxide as nanoreactors and templates for radical polymerisation. A new environmentally friendly method for synthesis of surfactant vesicles involving stabilisation using low pressure carbon dioxide will be applied to the synthesis of hollow polymeric nanoparticles and polymer of well-defined structure. The resulting polymeric structures will have applications in drug delivery and nano-engineered materials.
Functionalised biopolymers - a new class of renewable nano-engineered materials. Licella is an Australian start-up company, focusing on developing uses for the renewable resource lignocellulosic biomass; a fibrous material sourced principally from waste, such as that generated by forestry and agricultural operations. It is possible to use such waste and process it to separate the biomass components. This project proposes to modify these biomass fractions with living radical polymerisation (LPR) ....Functionalised biopolymers - a new class of renewable nano-engineered materials. Licella is an Australian start-up company, focusing on developing uses for the renewable resource lignocellulosic biomass; a fibrous material sourced principally from waste, such as that generated by forestry and agricultural operations. It is possible to use such waste and process it to separate the biomass components. This project proposes to modify these biomass fractions with living radical polymerisation (LPR) polymers to impart functionalities, such as antimicrobial properties, high tensile strengths and/or in-built photodegrability. New, high-performance sustainable materials like these will be the back-bone of the polymer/plastics industry of the future, replacing common plastics, sourced from non-renewable petrochemicals, with benign, sustainable plastics.Read moreRead less
Polymer-functionalised nanotubes: controlled formation by self-assembly. This project will develop new structures of nanotubes by combining peptide sequences and synthetic polymers. These nanostructured materials will form the basis of a wide range of technological applications, such as inorganic nanotubes, ion channels, drug carriers, and more broadly in nanotechnology and nanomedicine.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100033
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Green biopolymer nanocomposites facility: supercritical carbon dioxide characterisation and processing for nanomaterials and biopolymers. This facility will house characterisation and processing equipment for developing the next generation biopolymer materials. Novel biopolymers will be developed from natural and renewable resources using improved performance and lower energy supercritical carbon dioxide processing methods.
Polymer nanoparticles with gradient morphology for environmentally friendly aqueous coatings applications. The commercial and practical importance of coatings (paints) in today’s society can hardly be overstated. With the ongoing drive towards more environmentally friendly coating systems, there is a strong desire to replace traditionally employed solvent-based coatings with entirely waterborne systems. Waterborne coatings are a key measure by which the coating industry can meet requirements to ....Polymer nanoparticles with gradient morphology for environmentally friendly aqueous coatings applications. The commercial and practical importance of coatings (paints) in today’s society can hardly be overstated. With the ongoing drive towards more environmentally friendly coating systems, there is a strong desire to replace traditionally employed solvent-based coatings with entirely waterborne systems. Waterborne coatings are a key measure by which the coating industry can meet requirements to reduce emission of volatile organic compounds. However, maximum performance cannot be achieved currently using waterborne coatings, which in turn limits applications. The overall aim of this project is to develop environmentally friendly high-performance waterborne coatings that will enable replacement of currently employed solvent-based systems.Read moreRead less
A platform for the efficient optimisation of drug delivery using cross-linked micelles and thioclick-chemistry toward better anti-cancer treatment. The delivery of albendazole - an anti-cancer drug - will be improved by encapsulating the drug into nanoparticles. State of the art polymer chemistry will be employed to generate a versatile drug delivery system. The resulting nanoparticles will be able to better control drug delivery and to enhance cellular uptake of the drug.