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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.
Reinforcement of rubber products using nanostructured carbon materials. Reinforcement of rubber products using nanostructured carbon materials. This project aims to use the surface-functionalized nanostructured carbons as fillers to reinforce natural rubber. These fillers should significantly enhance the cross-linking between carbon and rubber matrix, leading to high-performance composite products with long lifetime, high thermal conductivity, high oil resistance and outstanding dynamic behaviou ....Reinforcement of rubber products using nanostructured carbon materials. Reinforcement of rubber products using nanostructured carbon materials. This project aims to use the surface-functionalized nanostructured carbons as fillers to reinforce natural rubber. These fillers should significantly enhance the cross-linking between carbon and rubber matrix, leading to high-performance composite products with long lifetime, high thermal conductivity, high oil resistance and outstanding dynamic behaviours. This project is expected to make Australia capable of fabricating superior rubber-based materials and devices that are comfortable, quiet and energy efficient, for use in aircrafts, automobiles and vessels. It should also reduce the use of non-degradable rubber materials, promoting Australia’s economic development and environment protection.Read moreRead less
Electrically conductive elastomeric composites by nanomaterials. Electrically conductive elastomeric composites by nanomaterials. This project aims to develop electrically conductive, mechanically robust, cost-effective elastomeric composites, by exploring new processing methods and studying the synergy between graphene sheets and multi-walled carbon nanotubes. Composites will be design, research and manufactured to suit the fabrication of rolling-resistance sensors that detect early-stage malfu ....Electrically conductive elastomeric composites by nanomaterials. Electrically conductive elastomeric composites by nanomaterials. This project aims to develop electrically conductive, mechanically robust, cost-effective elastomeric composites, by exploring new processing methods and studying the synergy between graphene sheets and multi-walled carbon nanotubes. Composites will be design, research and manufactured to suit the fabrication of rolling-resistance sensors that detect early-stage malfunctioning idler rolls. This technology could prevent the breakage of conveyor belts which are essential to the mining, processing and transportation of loose bulk materials; and improve the design and manufacturing of flexible sensors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100165
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
Thermal and mechanical simulation laboratory for light metals. The creation of a thermal and mechanical simulation laboratory for light metals will provide the critical infrastructure needed for generating new alloys and composites. This will extend Australia's competitive advantage in the design of better alloys for expanding applications in the construction, packaging, automotive and aerospace sectors.
Topology optimisation? An engineering approach to design of metamaterials. Metamaterials offer unusual physical properties and have significant potential to many technological innovations in precision instrument, medical, telecommunication, space and defence industries in the future. This project aims to develop a computational method for metamaterials so that they can be designed in an effective way.
Elastic Strain Engineered Transforming Metal Matrix-Nanowire Composite. This project aims to develop metallic composites of superior mechanical properties based on the principle of elastic strain coupling between ultrahigh-strength nanowires and phase transforming matrix. This new composite design concept has not been explored in the literature. Using the principle of elastic strain coupling, the composite is able to exhibit extraordinary mechanical properties unmatched by any existing engineeri ....Elastic Strain Engineered Transforming Metal Matrix-Nanowire Composite. This project aims to develop metallic composites of superior mechanical properties based on the principle of elastic strain coupling between ultrahigh-strength nanowires and phase transforming matrix. This new composite design concept has not been explored in the literature. Using the principle of elastic strain coupling, the composite is able to exhibit extraordinary mechanical properties unmatched by any existing engineering materials, including high strength, low Young’s modulus and high elastic strain limit. This new concept is a breakthrough and offers a unique opportunity to overcome a long-standing challenge in nanowire composite design, commonly known as the “valley of death”.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101176
Funder
Australian Research Council
Funding Amount
$407,000.00
Summary
High-performance flame retardant polymer foams by bioinspired nanocoating. This project aims to develop high-performance flame retardant polymer foams by creating a flame-retardant nanocoating on their surfaces based utilising layer-by-layer assembly. Polymer foams are widely used as thermal insulation materials for modern buildings because of their low density and excellent heat insulation. However they are highly flammable, which poses a great fire threat to life and property. The flame retard ....High-performance flame retardant polymer foams by bioinspired nanocoating. This project aims to develop high-performance flame retardant polymer foams by creating a flame-retardant nanocoating on their surfaces based utilising layer-by-layer assembly. Polymer foams are widely used as thermal insulation materials for modern buildings because of their low density and excellent heat insulation. However they are highly flammable, which poses a great fire threat to life and property. The flame retardancy, durability and wear-resistance of the resultant polymer foams will be tailored by manipulating the layer-by-layer construction parameters. The flame retardant polymer foams developed in this project will not only contribute to saving energy, but also to minimise the potential of fire hazards to life, property and the environment.Read moreRead less
Novel microwave processing of carbon nanotube/thermoplastic composites. This project aims to develop a novel fabrication process for carbon nano-tube (CNT) / thermoplastic composites. The method, with lab based ‘proof of concept’, uses microwaves and overcomes problems of dispersion and aggregation of CNTs, which limit properties of the nano-composites. At lab scale, a 50 per cent increase in stiffness of polypropylene and an increase in electrical conductivity with the addition of 0.5 weight pe ....Novel microwave processing of carbon nanotube/thermoplastic composites. This project aims to develop a novel fabrication process for carbon nano-tube (CNT) / thermoplastic composites. The method, with lab based ‘proof of concept’, uses microwaves and overcomes problems of dispersion and aggregation of CNTs, which limit properties of the nano-composites. At lab scale, a 50 per cent increase in stiffness of polypropylene and an increase in electrical conductivity with the addition of 0.5 weight percent CNT has been demonstrated. This project should unravel mechanisms by which these outstanding property improvements are achieved and will scale up the process to industrial level. Expected outcomes will be economical, lighter and stronger plastics for manufacturing applications such as rotational molding, transport and electronic packaging.Read moreRead less
Strain Matching Enabled Composite Design for Exceptional Mechanical Prowess. This project intends to develop phase-transforming matrix-nanolamellar composites of exceptional mechanical properties. Nanowires embedded in phase-transforming matrix composites achieve ultra-large elastic strains (around 6 per cent), thus ultra-high strengths. This project aims to build on this discovery and transcend the limitations of the nanowire composites by creating lattice-strain-matching enabled nanolamellar c ....Strain Matching Enabled Composite Design for Exceptional Mechanical Prowess. This project intends to develop phase-transforming matrix-nanolamellar composites of exceptional mechanical properties. Nanowires embedded in phase-transforming matrix composites achieve ultra-large elastic strains (around 6 per cent), thus ultra-high strengths. This project aims to build on this discovery and transcend the limitations of the nanowire composites by creating lattice-strain-matching enabled nanolamellar composites via innovative materials processing. The expected outcomes may lead to the design and creation of metallic composites of exceptional mechanical prowess and the development of close-to-application technology for fabrication of the composite materials.Read moreRead less
Origin and impact of solute clustering in light alloys. This project is designed to provide a physical metallurgy platform for understanding and interpreting the role of clusters of micro-alloying elements in precipitation in light alloys and aiding new alloy development. Phase transformations play an important role in determining the mechanical properties of many engineering materials. Understanding the origin and impact of solute clustering in phase transformations is crucial for achieving unp ....Origin and impact of solute clustering in light alloys. This project is designed to provide a physical metallurgy platform for understanding and interpreting the role of clusters of micro-alloying elements in precipitation in light alloys and aiding new alloy development. Phase transformations play an important role in determining the mechanical properties of many engineering materials. Understanding the origin and impact of solute clustering in phase transformations is crucial for achieving unprecedented properties in these materials. This project plans to combine atomic-scale characterisation and multi-scale computation to reveal the geometry and energetics of solute clusters and cluster-assisted nucleation in light alloys based on aluminium and magnesium. Applications may include the development of stronger and less costly metallic materials for the aerospace, aircraft and automotive industries.Read moreRead less