Discovery Early Career Researcher Award - Grant ID: DE210100056
Funder
Australian Research Council
Funding Amount
$433,746.00
Summary
Microstructured Nanohybrid Films for Passive Daytime Cooling. This project aims to develop a daytime radiative cooling surface without external energy requirement via novel microstructured nanohybrid film coatings to perpetually dump heat into cold outer space through the atmospheric window. The project expects to generate new fundamental knowledge in the area of building cooling materials, via multidisciplinary utilisation of cutting-edge construction materials and design. The expected outcome ....Microstructured Nanohybrid Films for Passive Daytime Cooling. This project aims to develop a daytime radiative cooling surface without external energy requirement via novel microstructured nanohybrid film coatings to perpetually dump heat into cold outer space through the atmospheric window. The project expects to generate new fundamental knowledge in the area of building cooling materials, via multidisciplinary utilisation of cutting-edge construction materials and design. The expected outcome of the project will place Australia in a competitive position in advanced green building infrastructure and highly demanded energy-saving technologies. This should provide benefits, such as significantly decreasing building energy consumption, and, thus reducing greenhouse gas emission.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
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
Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are d ....Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are disruptive advances in a number of key technological sectors, including biomedicine, pharmacy, energy and bioprocessing. Platform technology for cartilage tissue engineering has been chosen as an exemplar of the power of precision microparticles.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC210100023
Funder
Australian Research Council
Funding Amount
$4,943,949.00
Summary
ARC Training Centre in Bioplastics and Biocomposites. There is unprecedented growth in demand for bioderived and biodegradable materials. This Training Centre in Bioplastics and Biocomposites will capitalise on Australia’s abundance of the requisite natural bioresources to drive advances in technology for the development of bioplastic and biocomposite products for the new bioeconomy. The aim is to deliver leading edge research with a holistic focus on technical, social, policy and end of life so ....ARC Training Centre in Bioplastics and Biocomposites. There is unprecedented growth in demand for bioderived and biodegradable materials. This Training Centre in Bioplastics and Biocomposites will capitalise on Australia’s abundance of the requisite natural bioresources to drive advances in technology for the development of bioplastic and biocomposite products for the new bioeconomy. The aim is to deliver leading edge research with a holistic focus on technical, social, policy and end of life solutions, training a cohort of industry ready research specialists to underpin Australia’s transition to a globally significant bioplastics and biocomposites industry, while at the same time laying the foundations for accelerated growth in this space.Read moreRead less