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.
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
High-Performance Polymer Composites for Electrical Discharging. This project aims to address the problem of electrostatic discharge by developing new industry-compatible processing techniques and taking advantage of the synergy between graphene and carbon nanotubes and fibres. Electrostatic discharge due to accumulation of static electricity is a significant problem for lightweight polymer composites used in hazard environments, such as pumps for underground mining, oil and gas storage and satel ....High-Performance Polymer Composites for Electrical Discharging. This project aims to address the problem of electrostatic discharge by developing new industry-compatible processing techniques and taking advantage of the synergy between graphene and carbon nanotubes and fibres. Electrostatic discharge due to accumulation of static electricity is a significant problem for lightweight polymer composites used in hazard environments, such as pumps for underground mining, oil and gas storage and satellites. The outcomes will potentially transform the current manufacturing practice of anti-static composites for industry applications including mining, energy, space and agriculture. Read moreRead less
Core-shell nanofibrous bio-based flame retardants with reinforcement function. This project aims to develop high-performance bio-based flame retardants (FRs) by designing a novel core-shell nanofibrous FR system, combining exceptional flame retardant qualities and mechanical reinforcement to enhance the safe use of thermoplastic products. Thermoplastic products are widespread in building, electric and electronic, automobile and packaging products, but their intrinsic flammability poses great fir ....Core-shell nanofibrous bio-based flame retardants with reinforcement function. This project aims to develop high-performance bio-based flame retardants (FRs) by designing a novel core-shell nanofibrous FR system, combining exceptional flame retardant qualities and mechanical reinforcement to enhance the safe use of thermoplastic products. Thermoplastic products are widespread in building, electric and electronic, automobile and packaging products, but their intrinsic flammability poses great fire threats to the society. Flame retardants are key to producing fire-resistant plastic products with a low fire hazard rating. The novel bio-based flame retardant material developed by this project seeks to combine enhanced flame retardant properties and mechanical reinforcement functions. The outcomes of the project will demonstrate eco-friendly flame retardants and high performance flame retardant thermoplastic products.Read moreRead less
Toughening thermosets by highly ordered nanostructures. This research will develop a new technology to manufacture a class of novel ordered nanostructured thermosets. The outcome of this project will enable many existing and new engineering applications in the transportation, construction and microelectronics industries in Australia.
Engineering the trafficking of nanoparticles within cells. This project aims to engineer responsive nanoparticles capable of trafficking efficiently within cells. The site of release of therapeutic cargo has importance for improving the efficacy of many treatments, for example vaccine delivery. Therefore fundamental understanding of how nanoparticle structure can be engineered to control cellular behaviour is necessary. The project will engineer new polymeric nanomaterials and investigate the im ....Engineering the trafficking of nanoparticles within cells. This project aims to engineer responsive nanoparticles capable of trafficking efficiently within cells. The site of release of therapeutic cargo has importance for improving the efficacy of many treatments, for example vaccine delivery. Therefore fundamental understanding of how nanoparticle structure can be engineered to control cellular behaviour is necessary. The project will engineer new polymeric nanomaterials and investigate the impact of their structure on biological properties. The benefits of this project will include new fundamental insights into improving nanoparticle design for vaccine delivery, as well as the expansion of Australia’s knowledge base in the area of biodegradable polymers.Read moreRead less
Non-polyamide-based polymer membranes for efficient water processing. This project aims to develop an innovative, two-dimensional nanosheet scaffold polymerisation technique for the fabrication of advanced membranes. Membrane technology plays a key role in wastewater treatment and water desalination and purification. However, current membranes are not stable in an oxidation environment such as chlorine, which leads to significant membrane replacement costs. Through the development of new membran ....Non-polyamide-based polymer membranes for efficient water processing. This project aims to develop an innovative, two-dimensional nanosheet scaffold polymerisation technique for the fabrication of advanced membranes. Membrane technology plays a key role in wastewater treatment and water desalination and purification. However, current membranes are not stable in an oxidation environment such as chlorine, which leads to significant membrane replacement costs. Through the development of new membrane fabrication technology the project aims to produce non-polyamide-based polymer membranes with outstanding oxidation tolerance and separation properties. This will potentially simplify membrane processes, and improve water processing efficiency in wastewater treatment for power generation, and clean drinking water production.
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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
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
Formation and characterisation of continuous electrospun nanofibre yarns. Australia historically has a strong fibre and textile industry that can be augmented by embracing emerging nanotechnology. The proposed research will develop a technology that can greatly improve the productivity of nanofibres. These fibres can then be spun into continuous yarns and other form of textile products. The nanostructured products offer exceptional functions for biomedical and environmental applications. This ne ....Formation and characterisation of continuous electrospun nanofibre yarns. Australia historically has a strong fibre and textile industry that can be augmented by embracing emerging nanotechnology. The proposed research will develop a technology that can greatly improve the productivity of nanofibres. These fibres can then be spun into continuous yarns and other form of textile products. The nanostructured products offer exceptional functions for biomedical and environmental applications. This new technology has the potential to transform the Australian textile technology and fibre processing industry. Read moreRead less