Extremely lightweight and superelastic cellular materials. This project aims to synthesise a new generation of extremely lightweight, superelastic yet mechanically robust graphene-based cellular materials, develop new strategies to strengthen and functionalise them with other functional polymers or nanoparticles, and explore new techniques to characterise their unique mechanical, electrical and thermal properties for a range of potential applications. The new knowledge obtained would significant ....Extremely lightweight and superelastic cellular materials. This project aims to synthesise a new generation of extremely lightweight, superelastic yet mechanically robust graphene-based cellular materials, develop new strategies to strengthen and functionalise them with other functional polymers or nanoparticles, and explore new techniques to characterise their unique mechanical, electrical and thermal properties for a range of potential applications. The new knowledge obtained would significantly advance our understanding of extremely lightweight and multifunctional cellular materials as well as graphene-based bulk materials. Project outcomes are expected to help generate high value-added technological applications from natural graphite.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC180100005
Funder
Australian Research Council
Funding Amount
$4,889,410.00
Summary
ARC Training Centre in Surface Engineering for Advanced Materials. The ARC Training Centre in Surface Engineering for Advanced Materials aims to provide pathways for job creation and a high quality workforce in manufacturing. Surface engineering for advanced materials is a core need in all manufacturing sectors and controls the efficiency, productivity and sustainability of Australian industry. This Centre will integrate industry-university cooperation for applied training within an industrial s ....ARC Training Centre in Surface Engineering for Advanced Materials. The ARC Training Centre in Surface Engineering for Advanced Materials aims to provide pathways for job creation and a high quality workforce in manufacturing. Surface engineering for advanced materials is a core need in all manufacturing sectors and controls the efficiency, productivity and sustainability of Australian industry. This Centre will integrate industry-university cooperation for applied training within an industrial setting and will cover a spectrum of applications ranging from thin films to thick coatings and additive layered materials. The Centre will pursue outcomes that are reflected in terms of industry-fit researchers and deliver commercial benefits for industry.Read moreRead less
Structurally-bridged crystalline molecular sieve-polymer membranes. This project aims to produce a membrane platform technology for efficient and cost-effective separation in natural gas processing and petrochemicals, using crystalline sieve materials. It will address the mismatch of mechanical properties between crystalline molecular sieve materials (zeolites and metal organic frameworks) and polymers, and coating flaws which limit their use as gas separation membranes. It will create nano-rein ....Structurally-bridged crystalline molecular sieve-polymer membranes. This project aims to produce a membrane platform technology for efficient and cost-effective separation in natural gas processing and petrochemicals, using crystalline sieve materials. It will address the mismatch of mechanical properties between crystalline molecular sieve materials (zeolites and metal organic frameworks) and polymers, and coating flaws which limit their use as gas separation membranes. It will create nano-reinforcement in the coating and polymer substrate, with nano-bridges between them. The resulting membranes will be mechanically tough and separate better than existing membranes. Advanced membranes are expected to benefit fuel industries by reducing separation cost and energy consumption.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101662
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Non-Oxidative and Scalable Electrochemical Production of Functional Graphene and its Nanohybrids. The lack of cost-effective and scalable graphene production methods is the current bottleneck that impedes the commercialisation of advanced graphene-based nanomaterials. Novel electrochemical production of those functional materials directly from bulk graphite not only holds the key to the solution but also provides a non-oxidative route for the production of highly conductive graphene which is wel ....Non-Oxidative and Scalable Electrochemical Production of Functional Graphene and its Nanohybrids. The lack of cost-effective and scalable graphene production methods is the current bottleneck that impedes the commercialisation of advanced graphene-based nanomaterials. Novel electrochemical production of those functional materials directly from bulk graphite not only holds the key to the solution but also provides a non-oxidative route for the production of highly conductive graphene which is well suited for applications such as biosensing, energy storage and conversion. Besides achieving scientific breakthroughs in graphene electrochemistry, this project will directly benefit many Australian socio-economic objectives, including manufacturing of Australia's natural resources into valuable energy related products.Read moreRead less
A systems materials engineering strategy for hybrid ion capacitors. This project aims to develop a data science-driven approach to allow the use of materials systems engineering strategy to quantify the cell-level design of electrochemical energy storage devices such as hybrid ion capacitors. The intended outcomes of this project include new dynamic equivalent circuit models and a new quantitative approach to make the electrodes pairing predictable and realise their optimal design against the ne ....A systems materials engineering strategy for hybrid ion capacitors. This project aims to develop a data science-driven approach to allow the use of materials systems engineering strategy to quantify the cell-level design of electrochemical energy storage devices such as hybrid ion capacitors. The intended outcomes of this project include new dynamic equivalent circuit models and a new quantitative approach to make the electrodes pairing predictable and realise their optimal design against the needs of the specific applications. It will also demonstrate a combined strategy of data science and discipline-specific experiments and theories to advance the emerging field of materials systems engineering. Read moreRead less
A new design strategy for supercapacitors. This project aims to build a new equivalent electric circuit model using structurally tuneable graphene-based porous electrodes to establish a quantitative structure-property-performance relationship for super-capacitors. The new model will then be used to design novel electrode and device architectures to realise new energy storage devices with high usable storage capacity at high operation rates. This new computer-aided strategy will greatly accelerat ....A new design strategy for supercapacitors. This project aims to build a new equivalent electric circuit model using structurally tuneable graphene-based porous electrodes to establish a quantitative structure-property-performance relationship for super-capacitors. The new model will then be used to design novel electrode and device architectures to realise new energy storage devices with high usable storage capacity at high operation rates. This new computer-aided strategy will greatly accelerate the design of next-generation high-performance super-capacitors, and bring significant benefit to Australia's emerging knowledge-based manufacturing industry.Read moreRead less
The true potential and limitations of fibres. This project aims to understand the fibre spinning process of nanomaterials to identify their true potential and limitations in wearable applications. The project is expected to lead to multifunctional materials that allow design and production of smart functional fibres and textiles that store and convert energy and sense, monitor and respond to human activities and external environments. The project outcomes are expected to accelerate the transform ....The true potential and limitations of fibres. This project aims to understand the fibre spinning process of nanomaterials to identify their true potential and limitations in wearable applications. The project is expected to lead to multifunctional materials that allow design and production of smart functional fibres and textiles that store and convert energy and sense, monitor and respond to human activities and external environments. The project outcomes are expected to accelerate the transformation of the fibre industry, which will have far reaching implications across research disciplines and sectors critical to technology, health, social, and economic future.Read moreRead less
Physics-based equivalent circuit models for nanoporous electrodes. This project aims to develop new physics-based equivalent circuit models for ion/electron coupled dynamics in electrified porous nanomaterials via fusing latest simulation advances with machine learning approach. This project expects to meet the challenge of high-efficient and accurate dynamic models for accelerated design, accurate diagnosis, and optimal operation of electrochemical energy storage and conversion technologies. Th ....Physics-based equivalent circuit models for nanoporous electrodes. This project aims to develop new physics-based equivalent circuit models for ion/electron coupled dynamics in electrified porous nanomaterials via fusing latest simulation advances with machine learning approach. This project expects to meet the challenge of high-efficient and accurate dynamic models for accelerated design, accurate diagnosis, and optimal operation of electrochemical energy storage and conversion technologies. The outcome will be a paradigm shift of how equivalent circuit models are developed and used, informed by new scientific knowledge and data. The proliferation of the new models will allow design and operation of more efficient and durable technologies in energy industry, benefitting Australian economy and environment.Read moreRead less
Advanced separators for lithium-sulphur batteries. This project aims to develop new membranes for use as separators in lithium-sulphur batteries. Currently diffusion of polysulphides within these batteries reduces battery power and lifetime. The new membranes are intended to block polysulphide diffusion over an extended lifetime, while transporting the other ions needed for the battery to function. The project is expected to generate new membrane materials and further knowledge about the design, ....Advanced separators for lithium-sulphur batteries. This project aims to develop new membranes for use as separators in lithium-sulphur batteries. Currently diffusion of polysulphides within these batteries reduces battery power and lifetime. The new membranes are intended to block polysulphide diffusion over an extended lifetime, while transporting the other ions needed for the battery to function. The project is expected to generate new membrane materials and further knowledge about the design, synthesis and larger-scale production of membranes for electrochemical applications. This project will provide significant benefits by producing potentially lighter, longer-lasting and cheaper batteries than existing lithium-ion technologies, with the potential to accelerate the adoption of electric cars.Read moreRead less
Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project wi ....Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project will facilitate future large-scale adoption of renewable energy and many other new emerging technologies such as portable/wearable electronics, electric vehicles, and energy regeneration systems.Read moreRead less