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.
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.
Encoding Interactions and Printability into Hairy Colloidal Biomaterials. Printing mixtures of live cells and biomaterials (or 'BioInks') to make bespoke engineered tissues has the potential to enable personalised platforms for therapeutic discovery and organ replacement. Using a novel high throughput approach to materials synthesis, BioInk design and process optimisation, this project aims to discover new biomaterials and printing nozzles to help realise this potential. It will produce new insi ....Encoding Interactions and Printability into Hairy Colloidal Biomaterials. Printing mixtures of live cells and biomaterials (or 'BioInks') to make bespoke engineered tissues has the potential to enable personalised platforms for therapeutic discovery and organ replacement. Using a novel high throughput approach to materials synthesis, BioInk design and process optimisation, this project aims to discover new biomaterials and printing nozzles to help realise this potential. It will produce new insights in colloid science, cell-laden biomaterials design, and BioInk processing. Structure-property-function guides for colloid-based BioInks and quality-assured bioprinting as outcomes represent significant benefits for researchers and industries alike engaged in biofabrication, cell therapy and biotherapeutics.Read moreRead less
Self-reinforced biopolymer composites. This project will pioneer high performance and biodegradable composites using self-reinforced biopolymer composites. Composites can have poor properties due to interfacial issues, and this reduces their performance. By producing a fully self-reinforced (where the fibre and the polymer are the same type of polymer) polymer composites, the project will develop a way to improve properties, increase the use of biobased materials, and improve recyclability and b ....Self-reinforced biopolymer composites. This project will pioneer high performance and biodegradable composites using self-reinforced biopolymer composites. Composites can have poor properties due to interfacial issues, and this reduces their performance. By producing a fully self-reinforced (where the fibre and the polymer are the same type of polymer) polymer composites, the project will develop a way to improve properties, increase the use of biobased materials, and improve recyclability and biodegradability. Outcomes include greater understanding of design of self-reinforced biopolymer composites structure, processing and properties. This will produce opportunities for high performance biobased composite manufacturing and a growing circular plastics economy for Australia.Read moreRead less
Bioplastics in the environment: lifetimes and toxicology. Globally, governments are implementing policies to drive a move to a circular economy. In the process, new materials are being introduced whose potential impacts need to be understood before they are widely used. This project pioneers investigations into the rate and extent of biodegradation of biodegradable plastics in aquatic and soil environments and the associated ecotoxicology of this process. In particular, it aims to quantify the e ....Bioplastics in the environment: lifetimes and toxicology. Globally, governments are implementing policies to drive a move to a circular economy. In the process, new materials are being introduced whose potential impacts need to be understood before they are widely used. This project pioneers investigations into the rate and extent of biodegradation of biodegradable plastics in aquatic and soil environments and the associated ecotoxicology of this process. In particular, it aims to quantify the extent to which the surfaces of these materials accumulate environmental pollutants via adsorption and other mechanisms. The outcomes will include conceptual models of biodegradation across environments, including lifetimes and likely impacts, critical information for framing a sustainable plastics industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101549
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Creating a baker's yeast chassis cell via shikimate pathway engineering for production of sustainable, carbon-neutral plastic precursors for the future. From air bags to carpets, tyres and garden hoses, plastics shape our every day life. Coming from fossil fuels most are currently neither sustainable nor renewable. This project will engineer baker's yeast to produce plastic precursors from cane sugar in a fermentation process. This lays the basis for a sugar cane based chemical industry.
Next-generation lithography: photo-directing assembly of block copolymers. This project aims to introduce a novel approach to organising block polymers through the photochemical modification of the surface of a photo-sensitive polymer. Chemo-epitaxy is the science of organising materials on a surface decorated with chemical patterns. The process has the potential to revolutionise the manufacture of integrated circuits, enabling faster processors. This project expects to introduce innovative conc ....Next-generation lithography: photo-directing assembly of block copolymers. This project aims to introduce a novel approach to organising block polymers through the photochemical modification of the surface of a photo-sensitive polymer. Chemo-epitaxy is the science of organising materials on a surface decorated with chemical patterns. The process has the potential to revolutionise the manufacture of integrated circuits, enabling faster processors. This project expects to introduce innovative concepts in polymer chemistry and nanoscale assembly with the potential to advance a multi-billion-dollar industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101096
Funder
Australian Research Council
Funding Amount
$427,098.00
Summary
Programming Polymer Function via Ring-opening Polymerisation of Peptides. The project aims to set the foundation of a class of intelligent polymers, whose structure and function – including catalytic activity and biodegradability – can be readily programmed. In contrast to well-established radical polymerization techniques leading to all-carbon based backbones, the outlined research will develop technologies to incorporate short peptides into the backbones of synthetic polymers. The syntheticall ....Programming Polymer Function via Ring-opening Polymerisation of Peptides. The project aims to set the foundation of a class of intelligent polymers, whose structure and function – including catalytic activity and biodegradability – can be readily programmed. In contrast to well-established radical polymerization techniques leading to all-carbon based backbones, the outlined research will develop technologies to incorporate short peptides into the backbones of synthetic polymers. The synthetically adjustable amino acid sequence of the main chain embedded peptides will translate into the structure and function of the modular polymer. The DECRA will deliver unprecedented access towards tailor-made mechanical properties, catalytic activity and biodegradability of polymeric materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101788
Funder
Australian Research Council
Funding Amount
$415,498.00
Summary
Advanced Macromolecular Architecture via Selenium. The overarching aim of this project is to drastically expand the scale and scope of selenium-based macromolecular chemistry via safe, odor-free multicomponent reactions utilising elemental selenium. This project will develop new methods and techniques in drastically reducing the cost while increasing worker and environmental safety of industrial elastomers such as Spandex. Next the project will exploit selenium's sensitivity to ozonolysis to des ....Advanced Macromolecular Architecture via Selenium. The overarching aim of this project is to drastically expand the scale and scope of selenium-based macromolecular chemistry via safe, odor-free multicomponent reactions utilising elemental selenium. This project will develop new methods and techniques in drastically reducing the cost while increasing worker and environmental safety of industrial elastomers such as Spandex. Next the project will exploit selenium's sensitivity to ozonolysis to design a new instrument capable of extreme precision in monitoring oxidative damage in polymeric materials. Finally, selenium's unique reactivity will lend itself towards the next generation of smart materials which will be capable of completely reorganizing their structure down to the molecular level.Read moreRead less