Synthesising novel phases of carbon by shear-induced phase transformations. Carbon forms the hardest known solids and offers the opportunity for new materials with outstanding properties. The aim of this project is to establish a new technology for synthesising dense, diamond-like carbon materials without the need for high temperatures. The approach uses shear stress caused by non-hydrostatic compressions to drive phase changes in solids. Guided by modelling and using novel experimental techniqu ....Synthesising novel phases of carbon by shear-induced phase transformations. Carbon forms the hardest known solids and offers the opportunity for new materials with outstanding properties. The aim of this project is to establish a new technology for synthesising dense, diamond-like carbon materials without the need for high temperatures. The approach uses shear stress caused by non-hydrostatic compressions to drive phase changes in solids. Guided by modelling and using novel experimental techniques, this project seeks to understand and then exploit this remarkable phase change phenomenon. Expected outcomes include hard and tough coatings for high performance tools, impermeable encapsulations to enhance the longevity of bionic implants and a possible explanation for the mystery of deep earthquakes.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100365
Funder
Australian Research Council
Funding Amount
$462,237.00
Summary
Solar-driven catalytic production of high-value product from waste glycerol. Sustainable bio-refining requires an efficient and economical way of utilising the surplus amount of glycerol generated as a by-product in biodiesel industries. This project aims to construct an industry-scale solar-driven catalytic system to generate high-value-added chemicals and green hydrogen fuel from biomass wastes simultaneously. The structure-reactivity relationship of working catalysts will be established to fi ....Solar-driven catalytic production of high-value product from waste glycerol. Sustainable bio-refining requires an efficient and economical way of utilising the surplus amount of glycerol generated as a by-product in biodiesel industries. This project aims to construct an industry-scale solar-driven catalytic system to generate high-value-added chemicals and green hydrogen fuel from biomass wastes simultaneously. The structure-reactivity relationship of working catalysts will be established to fit the up-scale applications. The gained cutting-edge knowledge and technology will significantly contribute to biomass waste utilisation and sustainable fabrication, further bringing significant economic and social benefits by creating a new competitive business for Australian chemical and fuel areas. Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100048
Funder
Australian Research Council
Funding Amount
$466,097.00
Summary
Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway ....Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway and reduced energy for both ammonia production and removal. Recovered ammonia expects to produce valuable products, supporting agriculture industry and hydrogen economy. The developed membranes should enable water industry's shift into circular economy, providing significant economic and environmental benefits to Australia.Read moreRead less
Nanobionic plants. This project aims to develop nanobionic plants as network of semi-permanent sensors capable of rapid, sensitive, selective and unmanned detection and detoxification of chemical warfare agents in aquatic environments and in open air on-site, to allow timely and effective countermeasures. The anticipated goal is to advance the field of advanced manufacturing, environmental change, and nanotechnology with potential to support new national defence capabilities and to value-add Aus ....Nanobionic plants. This project aims to develop nanobionic plants as network of semi-permanent sensors capable of rapid, sensitive, selective and unmanned detection and detoxification of chemical warfare agents in aquatic environments and in open air on-site, to allow timely and effective countermeasures. The anticipated goal is to advance the field of advanced manufacturing, environmental change, and nanotechnology with potential to support new national defence capabilities and to value-add Australian manufacturing industries with innovative, disruptive technologies that lead to achievable opportunities to address its unique needs and to claim Australia’s position within the competitive global manufacturing and defence technology market.Read moreRead less
High-Performance and Evaporative Triboelectric Nanogenerators. This project aims to create high performance triboelectric nanogenerators (TENGs) with outstanding moisture wicking and thermal-moisture stability, while providing a comfortable platform for biomechanical energy harvesting and self-powered sensing. The project expects to generate new knowledge on simultaneous enhancement of output power and moisture management capability of tribo-textiles using interdisciplinary approaches. This shou ....High-Performance and Evaporative Triboelectric Nanogenerators. This project aims to create high performance triboelectric nanogenerators (TENGs) with outstanding moisture wicking and thermal-moisture stability, while providing a comfortable platform for biomechanical energy harvesting and self-powered sensing. The project expects to generate new knowledge on simultaneous enhancement of output power and moisture management capability of tribo-textiles using interdisciplinary approaches. This should overcome the bottleneck of output deterioration of TENGs under humid conditions and provide significant benefits by offering an attractive renewable energy source for driving low power sensors in the era of IoT and opening new opportunities in healthcare, sports, virtual reality and smart homes.
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