Discovery Early Career Researcher Award - Grant ID: DE140100569
Funder
Australian Research Council
Funding Amount
$372,952.00
Summary
Recovering helium from Australia’s natural gas: A case study for advanced adsorption processes to concentrate dilute gases. This project will deliver breakthroughs in gas separation technologies for the production of helium from natural gas. Global demand for helium in critical medical, scientific and industrial applications is projected to grow at around five per cent per annum. To overcome the forecast short falls in helium production, new low cost and energy efficient technologies to recover ....Recovering helium from Australia’s natural gas: A case study for advanced adsorption processes to concentrate dilute gases. This project will deliver breakthroughs in gas separation technologies for the production of helium from natural gas. Global demand for helium in critical medical, scientific and industrial applications is projected to grow at around five per cent per annum. To overcome the forecast short falls in helium production, new low cost and energy efficient technologies to recover helium from natural gas fields must be developed. This project will contribute novel microporous adsorbents, a better understanding of helium sorption kinetics and general methodologies for design of pressure swing adsorption processes to concentrate dilute mixtures.Read moreRead less
Improving the Durability and Performance of Hollow Fibre Membranes with Nanocomposite and Inorganic/organic Hybrid Materials. Water is a critical resource for societies worldwide and Australia is one of the driest nations on Earth. Options to treat ‘used’ or lower quality waters for reuse are becoming a necessity. This project aims to implement advanced nanotechnology solutions to improve performance characteristics of widely adopted water treatment membranes, which have the potential to reduce ....Improving the Durability and Performance of Hollow Fibre Membranes with Nanocomposite and Inorganic/organic Hybrid Materials. Water is a critical resource for societies worldwide and Australia is one of the driest nations on Earth. Options to treat ‘used’ or lower quality waters for reuse are becoming a necessity. This project aims to implement advanced nanotechnology solutions to improve performance characteristics of widely adopted water treatment membranes, which have the potential to reduce water treatment costs in Australia. This is made possible by the collaboration with Australia's largest manufacturer of water treatment membranes. The outcomes will lead towards a lower maintenance water treatment technology available to communities, at lower cost. The application of such a technology will span from local small scale to major installations worldwide.Read moreRead less
Characterising nanostructure functionality of conventional and advanced polymeric membranes using electrical impedance spectroscopy. Thin film membranes are an important separation process for industrial and municipal water treatment. This project will benefit Australian cities and industries by creating the tools to help reduce energy consumption associated with fouling of thin film membranes and indentify the next generation of efficient low fouling membranes.
Feedback destabilising control of electro-osmotic flow for reducing fouling and enhancing productivity of membrane systems. This project aims to develop a new approach to improving the productivity of membrane systems. With over $9 billion worth of membrane-based desalination plants either in operation, under construction or being planned in Australia, the expected outcomes of this project will lead to significant social and economic benefit and provide greater water security.
A fundamental study of milk ultrafiltration. The Dairy Industry is one of Australia's largest domestic and export industries. The fundamental knowledge and models developed in this project will be used to optimise dairy membrane processing. This will reduce water and energy use to improve the global competitiveness and reduce the environmental impact of the Australian Dairy Industry.
Development of Canonical Mist Filter Models. Over one million tonnes of oil (mist) is wasted every year – and emitted to the atmosphere through inefficient filtration. Over 50 per cent of energy usage in most process industries is for filtration and separation processes, yet mist filters and separators are largely designed by trial and error, resulting in sub-optimal, inefficient designs. Recent advances by the research team have, only now, made it possible to develop accurate models for such sy ....Development of Canonical Mist Filter Models. Over one million tonnes of oil (mist) is wasted every year – and emitted to the atmosphere through inefficient filtration. Over 50 per cent of energy usage in most process industries is for filtration and separation processes, yet mist filters and separators are largely designed by trial and error, resulting in sub-optimal, inefficient designs. Recent advances by the research team have, only now, made it possible to develop accurate models for such systems. This work intends to be the first to develop accurate, broadly applicable models for all processes in mist filters, thereby providing immense process efficiency benefits, together with improved worker and environmental protection, and less wastage of dwindling oil resources.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101687
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of ....Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of the fabrication time compared to normal slow calcination. The outcomes of this new technology aims to make inorganic membranes a commercial reality and maximize the membrane manufacturing capability and productivity of petrochemcial, chemical and clean coal/energy industries.Read moreRead less
Designing high performance gas separation by interfacial diffusion membrane. This project aims to develop a new generation of interfacial diffusion membranes for industrial gas separations including carbon dioxide removal, nitrogen gas enrichment, methane purification and air separation. The project focuses on advancing separation technologies for the petrochemical, natural gas, and clean energy industries in the mining sector. The project is expected to reveal new separation properties and perf ....Designing high performance gas separation by interfacial diffusion membrane. This project aims to develop a new generation of interfacial diffusion membranes for industrial gas separations including carbon dioxide removal, nitrogen gas enrichment, methane purification and air separation. The project focuses on advancing separation technologies for the petrochemical, natural gas, and clean energy industries in the mining sector. The project is expected to reveal new separation properties and performance based on highly selective interfacial diffusion membranes. The project will also create new scientific knowledge about the role of functional surfaces and nanostructures that will not only facilitate new membrane designs but also offer new, more cost-effective devices for solar conversion, energy storage and harvesting, biomedical applications, sensing and information technology.Read moreRead less
Industrial biotechnology for improved manufacture of medicinal alkaloids. Industrial biotechnology for improved manufacture of medicinal alkaloids. This project aims to develop a new semi-synthetic route for the manufacture of Codeine from Thebaine. Codeine is manufactured by the chemical conversion of poppy-derived Morphine, which is low yielding and environmentally unfriendly. This project will investigate and optimise two key enzymes in the biosynthetic pathway to Codeine and develop an innov ....Industrial biotechnology for improved manufacture of medicinal alkaloids. Industrial biotechnology for improved manufacture of medicinal alkaloids. This project aims to develop a new semi-synthetic route for the manufacture of Codeine from Thebaine. Codeine is manufactured by the chemical conversion of poppy-derived Morphine, which is low yielding and environmentally unfriendly. This project will investigate and optimise two key enzymes in the biosynthetic pathway to Codeine and develop an innovative bioreactor to achieve high yield. It will research industrial biotransformations, providing a greener and cheaper process for increased global access to Codeine. Australian opiate manufacturing is expected to benefit from value adding and increased flexibility introduced by a biotechnology approach.Read moreRead less
New fertiliser technologies for sustained food security. This project aims to provide fundamental research to develop next-generation fertiliser products that will improve nitrogen use efficiency, and reduce nitrogen losses in food production systems. It will achieve this goal through a multidisciplinary approach combining experts in synthetic and free radical chemistry, chemical engineering and soil science, with a strong commitment from a fertiliser industry partner. Society is facing the tri ....New fertiliser technologies for sustained food security. This project aims to provide fundamental research to develop next-generation fertiliser products that will improve nitrogen use efficiency, and reduce nitrogen losses in food production systems. It will achieve this goal through a multidisciplinary approach combining experts in synthetic and free radical chemistry, chemical engineering and soil science, with a strong commitment from a fertiliser industry partner. Society is facing the triple challenges of food security, environmental degradation and climate change The availability of new, highly-efficient fertilisers is critical for addressing these challenges, and for the competitive advantage of the Australian fertiliser industry.Read moreRead less