Flow process and visible-light driven reactions for polymer manufacturing. This project aims to develop rapid, scalable light-driven continuous flow processing techniques that allow the production of value-added synthetic polymers that cannot be achieved by existing technologies. The project will take advantage of the spatio-temporal control of the light mediated polymerisation with flow process to achieve control over the primary structure, the sequential arrangement of monomer units in a polym ....Flow process and visible-light driven reactions for polymer manufacturing. This project aims to develop rapid, scalable light-driven continuous flow processing techniques that allow the production of value-added synthetic polymers that cannot be achieved by existing technologies. The project will take advantage of the spatio-temporal control of the light mediated polymerisation with flow process to achieve control over the primary structure, the sequential arrangement of monomer units in a polymer chain and the molecular weight distribution. The project will result in the preparation of functional polymers containing a specific arrangement of monomers in the polymer chain and a precise distribution of polymer chains. The development of such process will result in the development of advanced materials.Read moreRead less
Engineering nanostructured graphene-based semiconductor photocatalysts. Harnessing solar energy and converting it into useful chemical energy efficiently is the expected outcome of the project. Given the strategic solar-geographical position of Australia, solar photocatalysis is a leading option for utilising our renewable energy resources to applications relating to energy conversion and environmental remediation.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100115
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploi ....High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploit interfacial phenomena and to tailor processing-microstructure-composition correlations, so as to design new materials with the best performance possible. Probes with unique capabilities will measure surface morphology, optical properties, elemental composition and crystallographic phase.The facility will be the first in Australia to offer a comprehensive study of structure and properties at high temperature.Read moreRead less
Neuromorphic Sensing and Diagnostics with Carbon: Towards a Biomimetic Nose. Neuromorphic electronics emulates cognitive processes of the brain and like the brain, is capable of extracting features and recognising patterns within data with extremely low energy requirements. Carbon materials are naturally adapted to neuromorphic electronics and uniquely form a compatible interface for sensing molecules in liquid and gaseous media. This project aims to develop a carbon-based neuromorphic electroni ....Neuromorphic Sensing and Diagnostics with Carbon: Towards a Biomimetic Nose. Neuromorphic electronics emulates cognitive processes of the brain and like the brain, is capable of extracting features and recognising patterns within data with extremely low energy requirements. Carbon materials are naturally adapted to neuromorphic electronics and uniquely form a compatible interface for sensing molecules in liquid and gaseous media. This project aims to develop a carbon-based neuromorphic electronic sensing device and couple it with carbon based neuromorphic pattern recognition technology to build an ‘artificial nose’ for improved health and environmental monitoring. Intended outcomes will include a technology for low-cost and rapid diagnostic services.
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Discovery Early Career Researcher Award - Grant ID: DE140101056
Funder
Australian Research Council
Funding Amount
$380,156.00
Summary
Rational Design of Plasmonic Nanoassemblies for Rapid and Multiplexed Point-of-Care Diagnosis by Surface-enhanced Raman Spectroscopy (SERS). The central aim of this project is to develop a novel technology/sensor platform for rapid, quantitative, multiplexed and highly sensitive point-of-care diagnostics using surface-enhanced Raman spectroscopy (SERS) as the read-out approach. Three-dimensional plasmonic superstructures as novel SERS labels will be synthesised and characterised at single-partic ....Rational Design of Plasmonic Nanoassemblies for Rapid and Multiplexed Point-of-Care Diagnosis by Surface-enhanced Raman Spectroscopy (SERS). The central aim of this project is to develop a novel technology/sensor platform for rapid, quantitative, multiplexed and highly sensitive point-of-care diagnostics using surface-enhanced Raman spectroscopy (SERS) as the read-out approach. Three-dimensional plasmonic superstructures as novel SERS labels will be synthesised and characterised at single-particle level and the choice of optimal SERS-active three-dimensional superstructures for use will be guided by empirical structure-activity correlations in combination with computer simulations. Tumour biomarkers for breast cancer will be employed as the model target for establishing the detection platform in a portable configuration for point-of-care diagnostics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100098
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Advanced facility for next generation sustainable energy, biomedical & nano-imaging optical fibre technologies. Remote optical fibre technologies are the way forward for effective and safe monitoring of many industries, and will play a big part in the sustainability of Australia's core oil, gas and alternative energy sectors. They are equally important to health industry applications, particularly in medical and imaging technologies. This facility brings together world-class Australian expertise ....Advanced facility for next generation sustainable energy, biomedical & nano-imaging optical fibre technologies. Remote optical fibre technologies are the way forward for effective and safe monitoring of many industries, and will play a big part in the sustainability of Australia's core oil, gas and alternative energy sectors. They are equally important to health industry applications, particularly in medical and imaging technologies. This facility brings together world-class Australian expertise—from across nine universities—in advanced structured optical fibres, complex fibre diagnostic systems, nanoscale imaging, and environment monitoring, to design and implement the next generation of technologies that will reduce the impact of climate change through reduced energy consumption and vastly improved health diagnostics.Read moreRead less
Room Temperature Rechargeable Sulphur Batteries. The project will lead to the development of low cost sulphur rechargeable batteries for electric vehicles and hybrid electric vehicles and will contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. The project will take the incentive in establishing a leading national position in the development of low cost energy storage technology. The Partner Organisation, Nipress, has a close con ....Room Temperature Rechargeable Sulphur Batteries. The project will lead to the development of low cost sulphur rechargeable batteries for electric vehicles and hybrid electric vehicles and will contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. The project will take the incentive in establishing a leading national position in the development of low cost energy storage technology. The Partner Organisation, Nipress, has a close connection to Australia. The company has imported raw materials (metal lead, 8000 tons) from Australia every year. The success of sulphur batteries technology will increase the opportunity of Nipress using more Australian raw materials.
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Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without cau ....Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without causing any environmental damage. This unique technology will also help to address clean energy generation, which is in line with H2 economy plan by Australia government, and provide opportunities for new industries that will benefit Australian economy.Read moreRead less
Nanoscale heating towards high efficient nitrogen reduction reduction. This project aims to develop nanoscale heating technique using AC magnetic field for efficient synthesis of ammonia, widely used for fertiliser and having potential for hydrogen storage. This project is to introduce nanoscale heating concept by heating catalyst only but not solution in electrochemical catalysis to achieve high catalytic activity. Expected outcome is the creation of low cost catalysts having high selectivity a ....Nanoscale heating towards high efficient nitrogen reduction reduction. This project aims to develop nanoscale heating technique using AC magnetic field for efficient synthesis of ammonia, widely used for fertiliser and having potential for hydrogen storage. This project is to introduce nanoscale heating concept by heating catalyst only but not solution in electrochemical catalysis to achieve high catalytic activity. Expected outcome is the creation of low cost catalysts having high selectivity and formation rate for ammonia production. This unique technology has the potential to replace current ammonia production based on Haber-Bosch process, which consumes 2% of world energy and contributes 3% of overall CO2 emission. The project provides opportunities for new industries that will benefit Australian economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100504
Funder
Australian Research Council
Funding Amount
$384,000.00
Summary
Interphases and interfaces of nanomaterials in potassium-ion batteries. This project aims to improve the fundamental understanding of interfacial interactions in multicomponent materials, which is a critical precursor to successfully designing and experimentally validating novel layered sulphide systems for potassium-ion batteries. A new layered structure construction technique will be employed to enhance the intrinsic electronic and ionic conductivities in the anode by controllable interphase a ....Interphases and interfaces of nanomaterials in potassium-ion batteries. This project aims to improve the fundamental understanding of interfacial interactions in multicomponent materials, which is a critical precursor to successfully designing and experimentally validating novel layered sulphide systems for potassium-ion batteries. A new layered structure construction technique will be employed to enhance the intrinsic electronic and ionic conductivities in the anode by controllable interphase and interface engineering. The expected outcomes of this project are to generate potassiumion batteries with high energy density, high safety, and long cycle life for next generation energy storage. This project should give Australia a competitive edge in the globally emerging sustainable manufacturing and energy-storage technologies.Read moreRead less