Bioinspired interfaces for improved carbon fibre composite performance. Carbon fibre composites, where carbon fibres are embedded in a polymer matrix, are gradually replacing traditional materials such as steel. For example, composites make up 50 per cent of Boeing’s 787 Dreamliner, resulting in a 20 per cent improvement in fuel economy. There is significant scope for improving the damage tolerance of these materials. A fundamental lack of understanding around the fibre matrix interface currentl ....Bioinspired interfaces for improved carbon fibre composite performance. Carbon fibre composites, where carbon fibres are embedded in a polymer matrix, are gradually replacing traditional materials such as steel. For example, composites make up 50 per cent of Boeing’s 787 Dreamliner, resulting in a 20 per cent improvement in fuel economy. There is significant scope for improving the damage tolerance of these materials. A fundamental lack of understanding around the fibre matrix interface currently limits the development of new composite systems to overcome the problems with damage tolerance. This project takes inspiration from nature to develop a fundamental understanding of the interfaces within carbon fibre composites and optimise their behaviour via model-guided surface and interface engineering. Read moreRead less
Engineering Processable, Tough Hydrogels with Biological Activity. The project aims to design a new class of tough hydrogels to address issues in engineering complex soft and robust structures. These hydrogels have superior properties compared with current materials as they are biologically active, processable by various manufacturing techniques, elastic and have a capacity for rapid self-recovery that are ideal for soft tissues. Their physical property is tunable by modification of their compos ....Engineering Processable, Tough Hydrogels with Biological Activity. The project aims to design a new class of tough hydrogels to address issues in engineering complex soft and robust structures. These hydrogels have superior properties compared with current materials as they are biologically active, processable by various manufacturing techniques, elastic and have a capacity for rapid self-recovery that are ideal for soft tissues. Their physical property is tunable by modification of their compositions that enable construction of complex seamless structure such as valved conduit with anistropic property. Expected outcomes of this project include new insights into material design, multi-physics modelling, and multi-material additive manufacturing for broad applications in soft robotics and medical implants.Read moreRead less
Hybrid photocatalytic nanomaterials for water purification. This project aims to synthesise and characterise a range of porous photocatalytic materials (materials that absorb light to catalyse a reaction), and to establish high-throughput processes to simultaneously test the effectiveness of multiple photocatalytic materials. This interdisciplinary project expects to develop two new techniques that will lead to faster materials optimisation of materials that breakdown organic pollutants in water ....Hybrid photocatalytic nanomaterials for water purification. This project aims to synthesise and characterise a range of porous photocatalytic materials (materials that absorb light to catalyse a reaction), and to establish high-throughput processes to simultaneously test the effectiveness of multiple photocatalytic materials. This interdisciplinary project expects to develop two new techniques that will lead to faster materials optimisation of materials that breakdown organic pollutants in water under light irradiation. The intended outcomes include the production of industrially relevant photocatalysts and building capability in Australia to decrease photocatalytic testing time and cost. This should provide significant benefits to industry and the environment, and have an impact on human health.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100090
Funder
Australian Research Council
Funding Amount
$1,136,244.00
Summary
Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engin ....Xe-plasma dual beam for advanced future materials. This project aims to establish a state of the art Xe-Plasma dual-beam facility providing characterisation and fabrication capabilities to Australia’s research community. The project will use two beams - one Xe, the other electrons - to mill the surface of bulk materials which are subsequently analysed by electron or ion beam techniques to determine atomic-scale microstructure(s) and compositions. Anticipated outcomes are advanced materials engineering and new knowledge about ancient and future materials. This is expected to provide significant advances across a variety of fields including material science, engineering and geology and enhance trans-disciplinary collaborations.Read moreRead less
Bio-inspired electro catalysts for gas reduction reactions: towards electrochemical ammonia production under ambient conditions. This project will develop solutions to replace the current energy inefficient method for ammonia production, which are a significant contribution to Greenhouse Gas emissions. A more energy efficient system will be developed from a new class of composite gas-reduction catalysts integrated into functional electrochemical cells.
Electronic coupling and nanoscale engineering of two-dimensional nanojunctions. This project aims to improve the design of photovoltaic, energy storage, and nanocatalytic devices by using quantum-size tuning, orientation control, strain engineering, and surface modification to manipulate the electronic coupling and charge transfer of two-dimensional nanojunctions. The limitations of and potential environmental damage from fossil-fuel-based energy resources have increased interest in renewable en ....Electronic coupling and nanoscale engineering of two-dimensional nanojunctions. This project aims to improve the design of photovoltaic, energy storage, and nanocatalytic devices by using quantum-size tuning, orientation control, strain engineering, and surface modification to manipulate the electronic coupling and charge transfer of two-dimensional nanojunctions. The limitations of and potential environmental damage from fossil-fuel-based energy resources have increased interest in renewable energy research. The expected outcomes are electron-scale understanding of the tuneable functionalisation of two-dimensional nanojunctions and the design of low-cost and high-efficiency renewable energy devices.Read moreRead less
Tailoring geopolymer concretes for sustainable development. This project will benefit Australia by enhancing the wider uptake of environmentally friendly geopolymer concretes. These materials are now commercially available in Australia, and provide the opportunity to obtain value from multiple millions of tonnes of industrial wastes (coal fly ash and metallurgical slags). An Australian company, Zeobond, is currently the world's leading commercial producer of geopolymers, and is collaborating in ....Tailoring geopolymer concretes for sustainable development. This project will benefit Australia by enhancing the wider uptake of environmentally friendly geopolymer concretes. These materials are now commercially available in Australia, and provide the opportunity to obtain value from multiple millions of tonnes of industrial wastes (coal fly ash and metallurgical slags). An Australian company, Zeobond, is currently the world's leading commercial producer of geopolymers, and is collaborating in this project to develop a scientific understanding of how best to formulate durable geopolymer concretes. Geopolymer concrete will provide the opportunity to reduce Australia's CO2 emissions by over a million tonnes per year when implemented on a commercial scale.Read moreRead less
Preventing biological growth – a new generation anti-biofouling coatings. The project aims to improve anti-biofouling technology by developing a ‘smart and green’ coating that requires no toxic biocides and makes use of copper already present in the water. Biofouling is the unwanted attachment and growth on surfaces in water; it causes significant problems on ships and in drinking water systems, and damages infrastructure and capital investment. Biofouling also carries a significant risk of spre ....Preventing biological growth – a new generation anti-biofouling coatings. The project aims to improve anti-biofouling technology by developing a ‘smart and green’ coating that requires no toxic biocides and makes use of copper already present in the water. Biofouling is the unwanted attachment and growth on surfaces in water; it causes significant problems on ships and in drinking water systems, and damages infrastructure and capital investment. Biofouling also carries a significant risk of spreading diseases and environmental damage through the introduction of invasive marine species. Existing coatings release highly toxic substances into the water, causing untold environmental damage. This project offers a single, comprehensive solution for all of the above problems.Read moreRead less
Atomic scale information for the design of nanomaterials. This project aims to develop a new tool to measure the 3-D distribution of atoms within nanoparticles. For the rational design of nanoparticles, it is necessary to compare the atomic scale structure to the resulting performance. But this information is hard to access. This projects aims to develop new methods so that atom probe microscopy can be applied to experimentally measure the precise 3-D location and identity of the individual atom ....Atomic scale information for the design of nanomaterials. This project aims to develop a new tool to measure the 3-D distribution of atoms within nanoparticles. For the rational design of nanoparticles, it is necessary to compare the atomic scale structure to the resulting performance. But this information is hard to access. This projects aims to develop new methods so that atom probe microscopy can be applied to experimentally measure the precise 3-D location and identity of the individual atoms within nanoparticles, and apply them in the development of alloy catalyst nanoparticles that could make the sustainable production of liquid fuels from biomass commercially viable. These new tools would be useful across the wide range of engineering applications for which nanomaterials are currently being developed.Read moreRead less