Spinning Nanosheets for Versatile Applications. This project seeks to develop a highly versatile and innovative fibre spinning research platform for fabricating multifunctional hybrid fibres with unprecedented mechanical, electrical and electrochemical properties. The novel fibres to be produced can be assembled into macroscale architectures or be weaved into functional textiles that can feed into relevant technologies and Australian industries such as advanced textiles for wearable energy stora ....Spinning Nanosheets for Versatile Applications. This project seeks to develop a highly versatile and innovative fibre spinning research platform for fabricating multifunctional hybrid fibres with unprecedented mechanical, electrical and electrochemical properties. The novel fibres to be produced can be assembled into macroscale architectures or be weaved into functional textiles that can feed into relevant technologies and Australian industries such as advanced textiles for wearable energy storage and conversion, microelectrodes and sensors, and smart medical/biomedical platforms. More importantly, this project will have far reaching implications across a range of research disciplines, and ultimately sectors critical to Australia’s health, social, and economic future.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH200100035
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub in New Safe and Reliable Energy Storage and Conversion Technologies. This Research Hub addresses safety and reliability issues, and environmental impact of current energy storage and conversion technologies. The research will deliver a new generation of technologies for storage from small scale portable devices to large scale industrial applications, using recycled and natural materials, and eliminating the serious fire risk in current technologies. Outcomes include innovative ....ARC Research Hub in New Safe and Reliable Energy Storage and Conversion Technologies. This Research Hub addresses safety and reliability issues, and environmental impact of current energy storage and conversion technologies. The research will deliver a new generation of technologies for storage from small scale portable devices to large scale industrial applications, using recycled and natural materials, and eliminating the serious fire risk in current technologies. Outcomes include innovative integrated energy conversion and storage technologies and new energy materials and devices designed for different scale applications, leading to creation of start up companies and commercialisation opportunities for existing partners, benefiting both the Australian economy and potentially transforming the energy industry landscape.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
Development and application of WO3-Mica Multifunctional Nanocomposites . This project aims to develop innovative techniques to produce advanced tungsten oxide/metal oxide/mica composites for paint applications. The findings will be used to develop pearlescent paints for diverse applications in a range of industries, with the potential for huge benefits in improving the value of metal oxides and mica. The findings will be useful in the development of other new materials and provide a foundation f ....Development and application of WO3-Mica Multifunctional Nanocomposites . This project aims to develop innovative techniques to produce advanced tungsten oxide/metal oxide/mica composites for paint applications. The findings will be used to develop pearlescent paints for diverse applications in a range of industries, with the potential for huge benefits in improving the value of metal oxides and mica. The findings will be useful in the development of other new materials and provide a foundation for new applications such as photochromic and self-cleaning paints. This will generate opportunities to develop and apply advanced knowledge to solve significant problems in industry, leading to national economic growth by adding high values of mineral resources in Australia.
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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: DE230101637
Funder
Australian Research Council
Funding Amount
$431,318.00
Summary
Heterogeneous Molecular Catalysts for Carbon Dioxide Conversion. This project aims to develop a series of structure-tailored, activity-enhanced and selectivity-oriented heterogeneous molecular catalysts for efficiently converting carbon dioxide (CO2) into value-added fuels and chemicals. Innovations are expected in the rational design and engineering of materials, new mechanistic findings from computation and in-situ characterisation, and breakthroughs in CO2 conversion. Expected outcomes includ ....Heterogeneous Molecular Catalysts for Carbon Dioxide Conversion. This project aims to develop a series of structure-tailored, activity-enhanced and selectivity-oriented heterogeneous molecular catalysts for efficiently converting carbon dioxide (CO2) into value-added fuels and chemicals. Innovations are expected in the rational design and engineering of materials, new mechanistic findings from computation and in-situ characterisation, and breakthroughs in CO2 conversion. Expected outcomes include new synthesis methods, innovative multi-structural engineering strategies, thorough reaction mechanism understanding, and high-performance commercially-relevant CO2 reduction electrolysis. Benefits include a sustainable future for Australia with decreased CO2 emissions and increased green-fuel production.Read moreRead less
Low cost solution-processable 2D nanomaterials for smart windows. This project aims to develop low cost and scalable synthesis of the active functional nanomaterials in smart windows, their facile application techniques, and their integration into the glass manufacturing process. Smart windows, with thermochromic and electrochromic functionalities, will play important roles towards efficient energy usage and conservation (in terms of air-conditioning and lighting) in most buildings including off ....Low cost solution-processable 2D nanomaterials for smart windows. This project aims to develop low cost and scalable synthesis of the active functional nanomaterials in smart windows, their facile application techniques, and their integration into the glass manufacturing process. Smart windows, with thermochromic and electrochromic functionalities, will play important roles towards efficient energy usage and conservation (in terms of air-conditioning and lighting) in most buildings including offices, schools, and residential homes. . The intended outcome of this project is to facilitate the commercialisation of low-cost, energy-saving smart windows for efficient energy usage and conservation, which is an integral part of a sustainable environment.Read moreRead less
Composite Membranes for Energy-efficient Separation Technologies. Advanced separation membranes play a crucial role in the development of clean energy and sustainable water technologies. In this project, new membranes will be developed to substantially improve separation efficiencies in these areas.
Nanotechnology enabled electrochemical energy storage materials from indigenous natural graphite. This project aims to develop a technology package for reclamation of fine-fractions of indigenous natural graphite to create high-value, nano-engineered 'graphene-based' energy storage materials. A multidisciplinary team of experts in materials science, chemical engineering, physics and electrochemistry will address this issue of national priority.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100223
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Advanced X-ray diffraction facility for high energy and extreme conditions. X-ray powder diffraction is a powerful technique for determining the structure of matter at the atomic scale. This project will establish a new Australian capability for X-ray powder diffraction under extreme conditions that emulate real harsh service environments for advanced functional materials.