SYNTHESIS OF A NANO-STRUCTURED TITANIA SURFACE AND ITS APPLICATION IN PHOTOCATALYTIC OXIDATION FOR WATER TREATMENT. Australia is facing severe freshwater crisis. Although there is an increasing public awareness of saving and using water efficiently, re-using water/wastewater has been neglected. In Australia, 97% of city runoff and 86% of effluent water is unproductive. How to recycle and re-use them becomes an urgent issue. This project attempts to develop novel titania based photocatalysts to c ....SYNTHESIS OF A NANO-STRUCTURED TITANIA SURFACE AND ITS APPLICATION IN PHOTOCATALYTIC OXIDATION FOR WATER TREATMENT. Australia is facing severe freshwater crisis. Although there is an increasing public awareness of saving and using water efficiently, re-using water/wastewater has been neglected. In Australia, 97% of city runoff and 86% of effluent water is unproductive. How to recycle and re-use them becomes an urgent issue. This project attempts to develop novel titania based photocatalysts to convert organic contaminated water into reusable/potable freshwater. The project's innovation lies in the synthesis of highly reactive nano-structured titania surfaces in fixed form to solve downstream separation problem. Successful development of such photocatalysts will show significant environmental and socio-economic benefits to Australia.Read moreRead less
Tough bio-derived and biodegradable wood plastic composites. This project aims for the development of tough bio-based and biodegradable wood plastic composites (WPCs), directly addressing a key end-user demand that performance of bio-WPCs must be at least comparable with existing commercial WPCs. The project expects to generate key innovations such as developing a new, high performance, bio-based and biodegradable WPC by incorporating native spinifex-derived nano-cellulose fibres, ensuring excel ....Tough bio-derived and biodegradable wood plastic composites. This project aims for the development of tough bio-based and biodegradable wood plastic composites (WPCs), directly addressing a key end-user demand that performance of bio-WPCs must be at least comparable with existing commercial WPCs. The project expects to generate key innovations such as developing a new, high performance, bio-based and biodegradable WPC by incorporating native spinifex-derived nano-cellulose fibres, ensuring excellent, molecular-level dispersion with a novel low-cost and energy-efficient wet-mix technology. This will provide significant benefits as it will lead to new products and markets for the Australian forestry industry and for rural and indigenous Australia, maximising Australia’s competitive advantage in biomass-derived products.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC150100004
Funder
Australian Research Council
Funding Amount
$3,630,239.00
Summary
ARC Training Centre for Forest Value. ARC Training Centre for Forest Value. This training centre aims to build capacity to transform the Australian forest products sector by providing advanced training and research. In particular, it aims to train a workforce capable of improving resource utilisation and creating value at all stages along the forest-to-building supply chain. This should allow the sector to exploit emerging markets in the use of renewable materials. The centre’s partners range fr ....ARC Training Centre for Forest Value. ARC Training Centre for Forest Value. This training centre aims to build capacity to transform the Australian forest products sector by providing advanced training and research. In particular, it aims to train a workforce capable of improving resource utilisation and creating value at all stages along the forest-to-building supply chain. This should allow the sector to exploit emerging markets in the use of renewable materials. The centre’s partners range from forest managers to architects and engineers, to ensure a flow of information from forest to design and manufacture. The centre’s research, and the industry-ready graduates produced, should increase industry productivity, profitability and sustainability, and enable increased returns from Australia’s forests.Read moreRead less
Electronically Conducting Nanofibres and Assemblies. With the use of new techniques that have just emerged in the last two years and are receiving rapidly growing interest throughout the world, this project will bring to Australia a new nanofabrication platform for making a variety of complex nanostructures. Fundamental researches on these complex nanostructures will greatly advance nanoscience. New nanotechnologies will be developed to address some world-wide challenging problems, e.g. energy ....Electronically Conducting Nanofibres and Assemblies. With the use of new techniques that have just emerged in the last two years and are receiving rapidly growing interest throughout the world, this project will bring to Australia a new nanofabrication platform for making a variety of complex nanostructures. Fundamental researches on these complex nanostructures will greatly advance nanoscience. New nanotechnologies will be developed to address some world-wide challenging problems, e.g. energy conversion and storage, chemical/biological sensing and other micro- and nanoelectronic devices. This project will bring both breakthrough science and frontier technologies for building and transforming Australian industries and help place Australia at the forefront of nanotechnology. Read moreRead less
The characterization and pocessing of Australian grown hemp fibres. This project will, for the first time, systematically examine the characteristics and processing behaviour of Australian grown hemp fibres. The hemp industry is an emerging new industry in rural Australia. This research will tackle a number of complex problems concerning characterization, degumming, and processing of Australian grown hemp, and will engineer the finest and softest yarns as well as industrial products from this he ....The characterization and pocessing of Australian grown hemp fibres. This project will, for the first time, systematically examine the characteristics and processing behaviour of Australian grown hemp fibres. The hemp industry is an emerging new industry in rural Australia. This research will tackle a number of complex problems concerning characterization, degumming, and processing of Australian grown hemp, and will engineer the finest and softest yarns as well as industrial products from this hemp. This will position the local hemp industry as well fibre processing industry in a very strong position to meet the growing demand world wide on this "green" fibre.Read moreRead less
Understanding the Behavior of Single-Walled Carbon Nanotubes in Liquids. The imminent manufacture of Single Walled Carbon Nanotubes (SWNTs) at prices comparable to those of high-performance polymers such as Kevlar, will open up potential applications of SWNTs as high-performance fibres and coatings. A major challenge is the development of scalable processes for producing large objects made of SWNTs. This project, in collaboration with researchers at Rice and Stanford Universities, aims to unders ....Understanding the Behavior of Single-Walled Carbon Nanotubes in Liquids. The imminent manufacture of Single Walled Carbon Nanotubes (SWNTs) at prices comparable to those of high-performance polymers such as Kevlar, will open up potential applications of SWNTs as high-performance fibres and coatings. A major challenge is the development of scalable processes for producing large objects made of SWNTs. This project, in collaboration with researchers at Rice and Stanford Universities, aims to understand the principles that underlie the successful liquid state processing of SWNTs. The novel strategies that arise will cement Australia's position as a leading country for research in nanotechnology, and place it at the forefront of this field, with great potential for economic advantage.Read moreRead less
New hybrid fibres incorporating nano protein materials. This project aims to develop new cellulose fibres incorporating nano protein materials extracted from animal fibres such as wool. The structure and property of the new hybrid fibres will be studied. Combining cellulose and protein materials within a single fibre is a new and original concept. This will lead to the production of new fibres with enhanced attributes and add significant value to the multi-billion dollar animal fibre industry in ....New hybrid fibres incorporating nano protein materials. This project aims to develop new cellulose fibres incorporating nano protein materials extracted from animal fibres such as wool. The structure and property of the new hybrid fibres will be studied. Combining cellulose and protein materials within a single fibre is a new and original concept. This will lead to the production of new fibres with enhanced attributes and add significant value to the multi-billion dollar animal fibre industry in Australia. It will also benefit the collaborating country as the major consumer of animal fibres imported from AustraliaRead moreRead less
Formation and characterisation of continuous electrospun nanofibre yarns. Australia historically has a strong fibre and textile industry that can be augmented by embracing emerging nanotechnology. The proposed research will develop a technology that can greatly improve the productivity of nanofibres. These fibres can then be spun into continuous yarns and other form of textile products. The nanostructured products offer exceptional functions for biomedical and environmental applications. This ne ....Formation and characterisation of continuous electrospun nanofibre yarns. Australia historically has a strong fibre and textile industry that can be augmented by embracing emerging nanotechnology. The proposed research will develop a technology that can greatly improve the productivity of nanofibres. These fibres can then be spun into continuous yarns and other form of textile products. The nanostructured products offer exceptional functions for biomedical and environmental applications. This new technology has the potential to transform the Australian textile technology and fibre processing industry. Read moreRead less
Formation of organic pollutants in fires of treated and contaminated wood. This project quantifies the emission of dioxins and biphenyls in burning of treated and contaminated wood to provide data on whether combustion of such materials should be regulated in Australia and whether an educational campaign needs to be mounted to make public aware of this problem. For example, our preliminary results indicate that, timber treated with copper boron azole, a non-arsenic replacement for CCA preservat ....Formation of organic pollutants in fires of treated and contaminated wood. This project quantifies the emission of dioxins and biphenyls in burning of treated and contaminated wood to provide data on whether combustion of such materials should be regulated in Australia and whether an educational campaign needs to be mounted to make public aware of this problem. For example, our preliminary results indicate that, timber treated with copper boron azole, a non-arsenic replacement for CCA preservative, produces extremely high levels of dioxins, both in flames and in the ash. If the preliminary results are confirmed, this agent must be disallowed as a wood preservative in Australia, as it poses unacceptable risks to the Australian population and environment. Read moreRead less
Scouring and Dehairing Australian Cashmere Fibres. The project aims to develop a viable method of dehairing greasy Australian cashmere materials. Traditionally, cashmere materials are scoured or washed first, followed by dehairing to extract the useful fine cashmere fibres. This is expensive and water consumption for scouring is also high. The current project will overcome the difficulties in dehairing greasy cashmere and optimise the process of scouring dehaired cashmere fibres. Technology deve ....Scouring and Dehairing Australian Cashmere Fibres. The project aims to develop a viable method of dehairing greasy Australian cashmere materials. Traditionally, cashmere materials are scoured or washed first, followed by dehairing to extract the useful fine cashmere fibres. This is expensive and water consumption for scouring is also high. The current project will overcome the difficulties in dehairing greasy cashmere and optimise the process of scouring dehaired cashmere fibres. Technology developed in this project will reduce scouring cost and water consumption, improve dehairing yield, and increase the flexibility of cashmere scouring and processing, leading to a more sustainable Australian cashmere industry.Read moreRead less