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Next-generation computational models to understand human joints . This project aims to investigate human joint systems through combining state-of-the-art imaging and high-fidelity biomechanical models. The methods developed in this project are expected to generate new ways of studying the dynamic response of musculoskeletal tissues to activity, including how musculoskeletal physiology can adapt to biomechanical stimuli. Expected outcomes include establishing a non-invasive method for characteris ....Next-generation computational models to understand human joints . This project aims to investigate human joint systems through combining state-of-the-art imaging and high-fidelity biomechanical models. The methods developed in this project are expected to generate new ways of studying the dynamic response of musculoskeletal tissues to activity, including how musculoskeletal physiology can adapt to biomechanical stimuli. Expected outcomes include establishing a non-invasive method for characterising whole joint systems. This project will provide significant knowledge gain on the biomechanical regulation of human joints across form, function, dynamics and loading which may help across many facets of society to guide physical activity choices.Read moreRead less
Next generation titanium alloys for additive manufacturing. The rise of 3D printing creates unique opportunities for Australian manufacturers to participate in high value global supply chains. However, the lack of development in high quality printable materials is stopping manufacturers from accessing the full potential of 3D printing. This project aims to develop a design strategy for the next generation of titanium metals designed for 3D printing. This project expects to improve functionality ....Next generation titanium alloys for additive manufacturing. The rise of 3D printing creates unique opportunities for Australian manufacturers to participate in high value global supply chains. However, the lack of development in high quality printable materials is stopping manufacturers from accessing the full potential of 3D printing. This project aims to develop a design strategy for the next generation of titanium metals designed for 3D printing. This project expects to improve functionality of 3D printed metals with qualities that go beyond the most demanding industry acceptance criteria. This project should provide significant benefits by creating new capabilities and improving the productivity of Australian manufacturers while lowering the cost of products for consumers.Read moreRead less
Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project ....Parallel Lines: Ultra-dense optical systems for extreme data-rates. The project aims to explore methods to significantly expand global internet data rates, by using emerging ultra-dense optical technologies. The project plans to discover how novel existing and emerging tiny photonic chip devices may enable the use of new, unused optical spectral bands, and then enable 1000s of channels to be supported by exploiting newly available parallelism in both wavelength and space. Success in the project aims may enable speeds of up to 100 times greater than achievable today, in a variety of fibre optic systems. Connectivity is key to our society, so benefits may arise in both future-proofing key Australian data infrastructure, and in providing a roadmap to support exponential capacity growth over the coming decades.Read moreRead less
High-Performance and Evaporative Triboelectric Nanogenerators. This project aims to create high performance triboelectric nanogenerators (TENGs) with outstanding moisture wicking and thermal-moisture stability, while providing a comfortable platform for biomechanical energy harvesting and self-powered sensing. The project expects to generate new knowledge on simultaneous enhancement of output power and moisture management capability of tribo-textiles using interdisciplinary approaches. This shou ....High-Performance and Evaporative Triboelectric Nanogenerators. This project aims to create high performance triboelectric nanogenerators (TENGs) with outstanding moisture wicking and thermal-moisture stability, while providing a comfortable platform for biomechanical energy harvesting and self-powered sensing. The project expects to generate new knowledge on simultaneous enhancement of output power and moisture management capability of tribo-textiles using interdisciplinary approaches. This should overcome the bottleneck of output deterioration of TENGs under humid conditions and provide significant benefits by offering an attractive renewable energy source for driving low power sensors in the era of IoT and opening new opportunities in healthcare, sports, virtual reality and smart homes.
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2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomin ....2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomings. Expected outcomes will include improved electrochemical performance of materials and an integrated energy system utilizing these multi-functional materials to produce green hydrogen at low cost and high efficiency. The project should contribute largely to Australia’s transition to robust and affordable clean energy.Read moreRead less
Developing lithium metal batteries – a game-changer for renewable energy. This project aims to develop nanostructured lithium metal anodes for rechargeable lithium metal batteries with high energy density and excellent cycle life. Lithium metal batteries such as lithium-sulfur batteries and lithium carbon-dioxide batteries present great opportunities for long-range electric vehicles and high-efficient renewable energy storage. Through the rational structure design and advanced interface engineer ....Developing lithium metal batteries – a game-changer for renewable energy. This project aims to develop nanostructured lithium metal anodes for rechargeable lithium metal batteries with high energy density and excellent cycle life. Lithium metal batteries such as lithium-sulfur batteries and lithium carbon-dioxide batteries present great opportunities for long-range electric vehicles and high-efficient renewable energy storage. Through the rational structure design and advanced interface engineering, the developed lithium metal anodes are expected to overcome the critical issues that hindered their practical application for high-energy batteries. The success of this project will provide new technological solutions for next-generation energy storage devices.Read moreRead less
Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional ....Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional materials, mechanism, catalytic engineering, and sustainable separation processes. This project will provide significant benefits in renovating smart nanomaterials in advanced manufacturing and clean environmental technologies, promoting Australia’s economic development and environment protection.Read moreRead less
Bottom-up multiscale modelling of expansive soils in natural environments . Expansive soils, highly sensitive to the environment, undergo dramatic strength and volume changes. This project aims to advance our understanding of expansive soils under different temperatures, hydraulic conditions, mechanical loads, and aqueous salinities. The project expects to use a combination of multidisciplinary knowledge, multiscale experiments and numerical simulations. The outcomes are a new multiscale model a ....Bottom-up multiscale modelling of expansive soils in natural environments . Expansive soils, highly sensitive to the environment, undergo dramatic strength and volume changes. This project aims to advance our understanding of expansive soils under different temperatures, hydraulic conditions, mechanical loads, and aqueous salinities. The project expects to use a combination of multidisciplinary knowledge, multiscale experiments and numerical simulations. The outcomes are a new multiscale model and advanced analysis/design tool for evaluating the performance of expansive soils under different conditions. The outcomes should provide the efficient way to mitigate the significant damage caused to infrastructure by expansive soils and facilitate the application of expansive soil products in waste disposal systems.Read moreRead less
Nanobionic plants. This project aims to develop nanobionic plants as network of semi-permanent sensors capable of rapid, sensitive, selective and unmanned detection and detoxification of chemical warfare agents in aquatic environments and in open air on-site, to allow timely and effective countermeasures. The anticipated goal is to advance the field of advanced manufacturing, environmental change, and nanotechnology with potential to support new national defence capabilities and to value-add Aus ....Nanobionic plants. This project aims to develop nanobionic plants as network of semi-permanent sensors capable of rapid, sensitive, selective and unmanned detection and detoxification of chemical warfare agents in aquatic environments and in open air on-site, to allow timely and effective countermeasures. The anticipated goal is to advance the field of advanced manufacturing, environmental change, and nanotechnology with potential to support new national defence capabilities and to value-add Australian manufacturing industries with innovative, disruptive technologies that lead to achievable opportunities to address its unique needs and to claim Australia’s position within the competitive global manufacturing and defence technology market.Read moreRead less
Functional-unit-based hierarchical nanocomposites for sustainable future. This project aims to address the limitation of current water electrolysis technologies through the development of functional-unit-based hierarchical nanocomposites for renewable energy generation with high efficiency. This project expects to generate new knowledge in next-generation catalyst design based on the deconvolution of energy loss in water electrolysis. The expected outcomes include the design and fabrication of n ....Functional-unit-based hierarchical nanocomposites for sustainable future. This project aims to address the limitation of current water electrolysis technologies through the development of functional-unit-based hierarchical nanocomposites for renewable energy generation with high efficiency. This project expects to generate new knowledge in next-generation catalyst design based on the deconvolution of energy loss in water electrolysis. The expected outcomes include the design and fabrication of novel catalysts with low overpotentials for green hydrogen production. This should provide significant benefits, such as low energy consumption and low carbon dioxide emissions in hydrogen production and advanced manufacturing, to the progress of renewable energy technology and the sustainable development of modern society.Read moreRead less