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Production of hydrogen from biomass by integrated catalytic aqueous hydrolysis and reforming in subcritical water. The outcomes of this project will lead to the development of a novel process for efficient and cost-effective hydrogen production from renewable biomass using integrated hydrolysis and catalytic aqueous reforming at low temperatures. Such technological innovation will provide significant benefits to Australia as a whole for transition to a truly sustainable hydrogen economy. The nov ....Production of hydrogen from biomass by integrated catalytic aqueous hydrolysis and reforming in subcritical water. The outcomes of this project will lead to the development of a novel process for efficient and cost-effective hydrogen production from renewable biomass using integrated hydrolysis and catalytic aqueous reforming at low temperatures. Such technological innovation will provide significant benefits to Australia as a whole for transition to a truly sustainable hydrogen economy. The novel reaction system and research methodologies proposed in this proposal will certainly enhance Australia's science and technology capability and international competitiveness, in the area of reaction engineering. Also of the national benefit is the successful training of a postgraduate at PhD level who will no doubt add to future scientific research workforce.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100017
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
An integrated system for measuring thermoelectric properties of advanced materials. This facility will establish an integrated measuring system which will form the key step in developing thermoelectric materials. The instruments will support groundbreaking research in developing advanced materials with significant economic and environmental benefits for many industries, such as materials manufacturing and improving automobile energy efficiency.
Discovery Early Career Researcher Award - Grant ID: DE170100952
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A chemical looping process for carbon fibre production from plastics. This project aims to develop Mineral Looping Plastic Reforming (MLPR), a chemical looping reforming process for tonnage production of carbon nanofibers from plastic waste. This efficient process uses naturally occurring minerals (limestone, dolomite and ilmenite) to convert plastic waste to carbon nanofibers. The project will research the inner working of the MLPR process and the reforming reactions of plastics in the presence ....A chemical looping process for carbon fibre production from plastics. This project aims to develop Mineral Looping Plastic Reforming (MLPR), a chemical looping reforming process for tonnage production of carbon nanofibers from plastic waste. This efficient process uses naturally occurring minerals (limestone, dolomite and ilmenite) to convert plastic waste to carbon nanofibers. The project will research the inner working of the MLPR process and the reforming reactions of plastics in the presence of naturally occurring mineral mixtures. This project is expected to make Australia a leader in waste use, facilitate the uptake of abundant waste streams to produce high value products, and resolve sustainability, energy and environmental issues in Australia.Read moreRead less
Self-cleaning thin films for anti-reflective solar cell coatings. This project addresses an important industry need by designing a new class of functional composite coatings for efficiency and durability improvement of solar cells. A successful outcome will provide an important breakthrough in thin film technology applicable not only to solar panels but also other coating applications.
Adaptive nanofabrication of monolithic multifunctional sensing chips. This project aims to develop a new miniaturised graphene sensing platform integrating multiparameter sensing, wireless charging and data communication on a single chip to revolutionise the ubiquitous wireless sensing networks. By exploring the versatile laser nanofabrication, multiple devices can be inscribed into one flexible mini-chip for the first time. The chip can transform any objects into intelligent, multifunctional an ....Adaptive nanofabrication of monolithic multifunctional sensing chips. This project aims to develop a new miniaturised graphene sensing platform integrating multiparameter sensing, wireless charging and data communication on a single chip to revolutionise the ubiquitous wireless sensing networks. By exploring the versatile laser nanofabrication, multiple devices can be inscribed into one flexible mini-chip for the first time. The chip can transform any objects into intelligent, multifunctional and energy-efficient sensors and find enormous applications in advanced manufacturing, logistics, health monitoring, supply chain and security. It underpins almost every sector of our daily life, securing Australia’s internationally leading position in digitalisation and creating significant social and economic benefits.Read moreRead less
Designing new layered materials for efficient solar energy conversion. This project will address the important material need for efficient solar energy conversion and environmental purification. These advanced materials will provide innovative solar utilisation technologies for economical water purification, self-cleaning coatings, and improved process for hydrogen production.
Nanostructured materials for development of advanced lithium energy storage systems. This project is expected to bring several national benefits. Novel nanostructured electro-active materials and high energy density rechargeable lithium batteries will be developed. The application of advanced lithium batteries as power sources for electric vehicles (EVs) and hybrid electric vehicles (HEVs) will realise nearly zero emission transportation. The widespread usage of EVs and HEVs could significantly ....Nanostructured materials for development of advanced lithium energy storage systems. This project is expected to bring several national benefits. Novel nanostructured electro-active materials and high energy density rechargeable lithium batteries will be developed. The application of advanced lithium batteries as power sources for electric vehicles (EVs) and hybrid electric vehicles (HEVs) will realise nearly zero emission transportation. The widespread usage of EVs and HEVs could significantly reduce air pollution, improve urban environment and increase national energy security and energy independence.Read moreRead less
Solar rechargeable batteries for wearable electronics. This project aims to develop a new solar battery as a sustainable power source for future wearable electronics. The research will develop solar rechargeable Zinc-Manganese oxide batteries based on new stretchable microelectrodes and materials engineering for the direct storage of solar energy. Expected outcomes include new classes of planar-type solar batteries, functional microelectrodes and energy materials, as well as new knowledge genera ....Solar rechargeable batteries for wearable electronics. This project aims to develop a new solar battery as a sustainable power source for future wearable electronics. The research will develop solar rechargeable Zinc-Manganese oxide batteries based on new stretchable microelectrodes and materials engineering for the direct storage of solar energy. Expected outcomes include new classes of planar-type solar batteries, functional microelectrodes and energy materials, as well as new knowledge generated from collaborations across materials science, photoelectrochemistry and nanotechnology disciplines. These will not only expand the applications of solar batteries to a new domain of wearable electronics, but also may eventually lead to new industry advances in functional materials for clean energy.Read moreRead less
Designing integrated photocatalytic systems for simultaneous clean energy generation and water remediation. The proposal addresses the core issues of energy and water, two highly critical resources in Australia as well as worldwide. Utilising our geographically-abundant solar energy and through designing novel photocatalytic systems, the proposed research provides an ultimately clean solution by efficiently harnessing and converting the solar energy to hydrogen while remediating wastewater. Give ....Designing integrated photocatalytic systems for simultaneous clean energy generation and water remediation. The proposal addresses the core issues of energy and water, two highly critical resources in Australia as well as worldwide. Utilising our geographically-abundant solar energy and through designing novel photocatalytic systems, the proposed research provides an ultimately clean solution by efficiently harnessing and converting the solar energy to hydrogen while remediating wastewater. Given the high intensity and consistent solar output in Australia, such technology provides an almost ideal and sustainable outcome in terms of clean energy and water supply. Success in this area will place Australian researchers at the forefront of practical and functional photocatalytic technologiesRead moreRead less
Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding ....Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding of sodium-ion batteries, and provide techniques for the development of a promising low-cost system for renewable energy storage, which is urgently needed in smart electricity grids. Read moreRead less