NANO-SCALE CATALYST SYSTEMS FOR HYDROGEN GENERATION FOR FUEL CELLS. The project aims to develop nano-scale catalyst materials for micro-channel fuel processing systems. Micro-channel reactors have the benefits over conventional technology of being more compact and potential for much lower costs. This will assist in the development of hydrogen generation systems for fuel cells, as well as other chemical processing applications such as gas-to-liquids technology. The technology has the potential t ....NANO-SCALE CATALYST SYSTEMS FOR HYDROGEN GENERATION FOR FUEL CELLS. The project aims to develop nano-scale catalyst materials for micro-channel fuel processing systems. Micro-channel reactors have the benefits over conventional technology of being more compact and potential for much lower costs. This will assist in the development of hydrogen generation systems for fuel cells, as well as other chemical processing applications such as gas-to-liquids technology. The technology has the potential to generate significant IP in an evolving multi-billion dollar fuel cell industry. Support from Ceramic Fuel Cells Ltd. and the Gas Technology Institute will ensure that the work has an international as well as national perspective, and a route to exploitation.Read moreRead less
Development of Superflux Carbon Nanotube Membranes for Gas Separation. The project seeks to develop gas separation membranes displaying superfluxes - throughputs 10 to 100 times higher than current systems, with lower operating costs. There is compelling evidence that very high flow rates are achievable and they have been shown for single gas transport. Theory predicts that highly selective separations are possible, but this has not yet been experimentally shown - a key outcome from this proje ....Development of Superflux Carbon Nanotube Membranes for Gas Separation. The project seeks to develop gas separation membranes displaying superfluxes - throughputs 10 to 100 times higher than current systems, with lower operating costs. There is compelling evidence that very high flow rates are achievable and they have been shown for single gas transport. Theory predicts that highly selective separations are possible, but this has not yet been experimentally shown - a key outcome from this project. The applications are widespread and include separation of carbon dioxide from power station flue gas for sequestration, purification of natural gas and provision of pure component gases such as oxygen and nitrogen amongst others.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190101410
Funder
Australian Research Council
Funding Amount
$393,000.00
Summary
Structural and compositional controlled nanocarbon-based electrocatalyst. This project aims to develop highly effective carbon-based electro-catalysts for oxygen reduction by using elaborately designed metal-organic framework precursors. Oxygen reduction is a key cathodic reaction in clean energy technologies such as metal-air batteries and fuel cells. Expected outcomes of this project include carbon-based nanomaterials with optimised topological and compositional features. This project will bro ....Structural and compositional controlled nanocarbon-based electrocatalyst. This project aims to develop highly effective carbon-based electro-catalysts for oxygen reduction by using elaborately designed metal-organic framework precursors. Oxygen reduction is a key cathodic reaction in clean energy technologies such as metal-air batteries and fuel cells. Expected outcomes of this project include carbon-based nanomaterials with optimised topological and compositional features. This project will broaden the knowledge of designed synthesis of carbon-based nanocatalysts for oxygen reduction and provide a conceptual nanofabrication framework for preparing functional nanomaterials.Read moreRead less
Charge-driven self-assembly of nanocomposites of ionic polymers and oxide nanoparticles. This project addresses the materials needs in platform technologies for more efficient and cleaner means of generating energy and utilising energy. It also aims at better catalysts for cleaner chemical processes. The novel nanocomposites with significantly increased active ionic sites and higher ionic conductivity, and better activity in catalysis will lead to possible new breakthroughs in technologies for e ....Charge-driven self-assembly of nanocomposites of ionic polymers and oxide nanoparticles. This project addresses the materials needs in platform technologies for more efficient and cleaner means of generating energy and utilising energy. It also aims at better catalysts for cleaner chemical processes. The novel nanocomposites with significantly increased active ionic sites and higher ionic conductivity, and better activity in catalysis will lead to possible new breakthroughs in technologies for energy, environmental and self-cleaning materials. The fabrication approach developed are also applicable to other functional nanomaterials, providing new opportunities for innovative nanotechnology to clearer and greener chemical and energy industries.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100015
Funder
Australian Research Council
Funding Amount
$523,899.00
Summary
Integrated Tip-Enabled Nanofabrication and Characterisation at Atomic Scale. This project aims to establish the most advanced all-in-one multifunctional system going beyond the best system in the world. This facility is expected to combine tip-enabled nanofabrication, imaging, photo-/electrochemical, and electromechanical measurement to realise atomically precisely controlled nanofabrication, in-situ imaging, and real-time measurement of single active sites in micro and nanoscale devices.The pro ....Integrated Tip-Enabled Nanofabrication and Characterisation at Atomic Scale. This project aims to establish the most advanced all-in-one multifunctional system going beyond the best system in the world. This facility is expected to combine tip-enabled nanofabrication, imaging, photo-/electrochemical, and electromechanical measurement to realise atomically precisely controlled nanofabrication, in-situ imaging, and real-time measurement of single active sites in micro and nanoscale devices.The proposed facility features high-quality measurements in an unmatched spatial and temporal range, allowing studying physical and chemical phenomena that are difficult to detect using conventional methods. The proposed integrated system will be the first of its kind in Australia. Read moreRead less
New Pillared Nanoporous Materials for Hydrogen Production by Photoinduced Water Splitting. The increasing concern over the limited supply of conventional energy sources has triggered world-wide efforts in developing alternative energy generation systems. Hydrogen produced from sunlight and water is considered as an ultimate solution for the hydrogen economy. This project addresses the material needs for more efficient and cleaner means of generating/utilising energy. The novel nanoporous materia ....New Pillared Nanoporous Materials for Hydrogen Production by Photoinduced Water Splitting. The increasing concern over the limited supply of conventional energy sources has triggered world-wide efforts in developing alternative energy generation systems. Hydrogen produced from sunlight and water is considered as an ultimate solution for the hydrogen economy. This project addresses the material needs for more efficient and cleaner means of generating/utilising energy. The novel nanoporous materials with increased photocatalytic water splitting efficiency will lead to new breakthrough in technologies for energy conversion materials. The preparation approach is also applicable to other functional layered materials, providing new opportunities for innovative nanotechnology to more efficient and greener energy industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775548
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Advanced characterisation facilities for functional nanostructured materials. A critical factor that enhances frontier research is a set of advanced core research experimental facilities for material characterisation purposes. The proposed equipment aims to: (1) provide research facilities for advanced nanomaterial research; (2) improve national competitiveness and growth in a knowledge-based economy; and (3) foster local talented researchers in order to meet the strategic needs of the nation fo ....Advanced characterisation facilities for functional nanostructured materials. A critical factor that enhances frontier research is a set of advanced core research experimental facilities for material characterisation purposes. The proposed equipment aims to: (1) provide research facilities for advanced nanomaterial research; (2) improve national competitiveness and growth in a knowledge-based economy; and (3) foster local talented researchers in order to meet the strategic needs of the nation for a sustainable environment. These activities will revitalise Australia's leading role in creating new technologies with particular relevance to using advanced nanostructures for the production of clean air and water, and sustainable energy alternatives.Read moreRead less
Synthesis of Unique Mesoporous Graphitic Carbons and their Application to Fundamental Problems in Adsorption Science. The development of synthesis techniques to create porous graphitic carbons with highly ordered pore structures, easily accessible pore volume and good electrical conductivity can underpin technological advancements in many industrial applications such as energy storage, removal of pollutants from exhaust streams, direct-methanol fuel cells and lithium ion batteries. Techniques de ....Synthesis of Unique Mesoporous Graphitic Carbons and their Application to Fundamental Problems in Adsorption Science. The development of synthesis techniques to create porous graphitic carbons with highly ordered pore structures, easily accessible pore volume and good electrical conductivity can underpin technological advancements in many industrial applications such as energy storage, removal of pollutants from exhaust streams, direct-methanol fuel cells and lithium ion batteries. Techniques developed in this project are also applicable to creating other materials important to advanced sensors and optoelectronics. The fundamental study of water adsorption and hysteresis using these carbons will help us create better models for adsorption. This will underpin theoretical studies, characterisation and optimisation of carbon materials into the future. Read moreRead less
Multifunctional Porous Nanospheres Engineered Composite Membranes for Hydrogen and Methanol Fuel Cells. Increasing concerns about greenhouse gas emissions and dwindling petroleum supplies have driven the development and commercialisation of fuel cells. The development of novel nanocomposite membranes will possibly lead to the materials breakthrough necessary for advancing both hydrogen and methanol fuel cell technologies, significantly benefiting Australian clean energy supplies and in particul ....Multifunctional Porous Nanospheres Engineered Composite Membranes for Hydrogen and Methanol Fuel Cells. Increasing concerns about greenhouse gas emissions and dwindling petroleum supplies have driven the development and commercialisation of fuel cells. The development of novel nanocomposite membranes will possibly lead to the materials breakthrough necessary for advancing both hydrogen and methanol fuel cell technologies, significantly benefiting Australian clean energy supplies and in particular transport vehicles and portable devices. The synthesis strategies generated will be applicable to creating other functional nanoporous or nanocomposite materials for wider application. This project will also enhance the international reputation and impact of Australian research in the internationally focused fields of nanomaterials and fuel cell technology.Read moreRead less
NANOCOMPOSITE PROTON-CONDUCTING MEMBRANES FOR FUEL CELL APPLICATIONS. This project aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both ....NANOCOMPOSITE PROTON-CONDUCTING MEMBRANES FOR FUEL CELL APPLICATIONS. This project aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both hydrogen and methanol fuel cells, promising a revolutionary clean energy supply particularly for transport vehicles and mobile devices. The project addresses the synthesis and characterisation of nanostructured composite of proton-conducting nanoparticles, a key to high performance fuel cell membranes.Read moreRead less