Novel inkjet-printed organic solvent nanofiltration membranes. The pharmaceutical industry is one of fastest growing industries in Australia. Manufacturing pharmaceutical products requires the use of hazardous and expensive organic solvents, which are toxic for the environment and expensive to recover due to the energy intensive thermal process required. This project aims to discover and manufacture a novel, low-cost, chemically robust nanomaterial-based membrane using an industry scalable inkje ....Novel inkjet-printed organic solvent nanofiltration membranes. The pharmaceutical industry is one of fastest growing industries in Australia. Manufacturing pharmaceutical products requires the use of hazardous and expensive organic solvents, which are toxic for the environment and expensive to recover due to the energy intensive thermal process required. This project aims to discover and manufacture a novel, low-cost, chemically robust nanomaterial-based membrane using an industry scalable inkjet printing process. The membrane will be resistant to organic solvents while efficiently recovering valuable and hazardous organic solvents with minimum environmental footprint. It will effectively provide for the future growth of the Australian pharmaceutical industry while also having global applications.Read moreRead less
A novel ion-selective membrane for efficient lithium recovery . This project aims to fabricate a novel membrane that display selective lithium recovery from brine in a renewable energy driven electrochemical membrane technology. The fabrication of lithium selective membranes embedded with nanomaterials and metal organic framework will create new knowledge on the dynamics of ion-size sieving and accelerating lithium transportation. This project will provide significant environmental and economic ....A novel ion-selective membrane for efficient lithium recovery . This project aims to fabricate a novel membrane that display selective lithium recovery from brine in a renewable energy driven electrochemical membrane technology. The fabrication of lithium selective membranes embedded with nanomaterials and metal organic framework will create new knowledge on the dynamics of ion-size sieving and accelerating lithium transportation. This project will provide significant environmental and economic benefit by establishing a rapid and chemical free method to recover lithium affordably and orders of magnitude more efficiently than hard rock extraction. This project will bring significant commercial benefits to Australian mining industry, desalination and water treatment sectors.Read moreRead less
Optimising nanofiltration and reverse osmosis filtration processes for water recycling: effects of fouling and chemical cleaning on trace contaminant removal. In Australia, water recycling is considered a principal measure to manage the current ongoing water shortage and to better protect the environment. Membrane filtration processes play important roles in the treatment of reclaimed municipal wastewater. However, there is very limited knowledge regarding the reliability of such processes in re ....Optimising nanofiltration and reverse osmosis filtration processes for water recycling: effects of fouling and chemical cleaning on trace contaminant removal. In Australia, water recycling is considered a principal measure to manage the current ongoing water shortage and to better protect the environment. Membrane filtration processes play important roles in the treatment of reclaimed municipal wastewater. However, there is very limited knowledge regarding the reliability of such processes in removing trace contaminants from recycled water, which may result in unintended health consequences. This research will lead to a comprehensive understanding of the removal process of such contaminants by membrane filtration. Consequently, the likely avenue of risk can be eliminated and the treatment process can be optimised to achieve economic savings and environmental protection.Read moreRead less
Optimising Removal of Proteinaceous Foulants from Membranes. Removal of proteinacous foulants from membrane systems imposes both significant economic costs in terms of chemical usage as well as significant environmental costs in terms of water usage and production of effluents from the cleaning and rinsing waters. The outcome of this project should allow us to develop methods for the prediction and optimisation of membrane cleaning performance of relevance to major Australian industries includin ....Optimising Removal of Proteinaceous Foulants from Membranes. Removal of proteinacous foulants from membrane systems imposes both significant economic costs in terms of chemical usage as well as significant environmental costs in terms of water usage and production of effluents from the cleaning and rinsing waters. The outcome of this project should allow us to develop methods for the prediction and optimisation of membrane cleaning performance of relevance to major Australian industries including the dairy, food processing and water and waste water treatment industries.Read moreRead less
Highly Efficient Nanomotors for Autonomous Cell Recognition and Isolation. This project aims to develop next-generation self-driven nanomotors capable of long-range motion with highly controlled directionality for cell recognition, transportation and separation in complex biological environments, to allow autonomous and seamless cell sorting with high accuracy. The anticipated goal of this project is to advance the field of nanotechnology and advanced manufacturing with potential to support new ....Highly Efficient Nanomotors for Autonomous Cell Recognition and Isolation. This project aims to develop next-generation self-driven nanomotors capable of long-range motion with highly controlled directionality for cell recognition, transportation and separation in complex biological environments, to allow autonomous and seamless cell sorting with high accuracy. The anticipated goal of this project is to advance the field of nanotechnology and advanced manufacturing with potential to support new applications and to value-add Australia’s advanced manufacturing industry, presenting new opportunities for Australian MedTech industries with innovative, disruptive technologies to address its unique needs and to claim Australia’s position within the competitive global market.Read moreRead less
Flotation separation of nanoparticles. This project deals with the separation of fine nanoparticles suspended in water, by attachment to small gas bubbles. It aims to find a way of removing nanoparticles from water, or of separating one species from another. The process could be used for simple solids such as metal oxides, and for biological materials such as large molecules, viruses and small bacteria. The work will be both theoretical and experimental. This ground-breaking project will build u ....Flotation separation of nanoparticles. This project deals with the separation of fine nanoparticles suspended in water, by attachment to small gas bubbles. It aims to find a way of removing nanoparticles from water, or of separating one species from another. The process could be used for simple solids such as metal oxides, and for biological materials such as large molecules, viruses and small bacteria. The work will be both theoretical and experimental. This ground-breaking project will build upon past successes of the applicant, whose invention in the field of resource recovery is contributing close to $1 billion a year to Australia's exports.Read moreRead less
Development of High Performance Nanocomposite Filtration Membranes: Fabrication and Fouling Mechanisms. This project will develop high performance membranes for the filtration of water and wastewater using novel nanotechnology processes. This will reduce the costs and environmental impact of water treatment and risk from low-level chemical contaminants such as micropollutants. The project will also provide an enhanced technology base for producing low cost, hybrid inorganic-organic materials fo ....Development of High Performance Nanocomposite Filtration Membranes: Fabrication and Fouling Mechanisms. This project will develop high performance membranes for the filtration of water and wastewater using novel nanotechnology processes. This will reduce the costs and environmental impact of water treatment and risk from low-level chemical contaminants such as micropollutants. The project will also provide an enhanced technology base for producing low cost, hybrid inorganic-organic materials for widespread environmental, agricultural and food applications.Read moreRead less
Development of a novel adsorbent to extract rubidium from sea water. Disposal of rejected brine from seawater reverse osmosis desalination plants causes major pollution problems and existing solutions are expensive. Recovery of valuable metals such as rubidium (Rb) after further concentration of the brine will lead to environmental and economic benefits. This project aims to develop a novel electrospun nanofibre membrane distillation membrane to economically concentrate the brine and to develop ....Development of a novel adsorbent to extract rubidium from sea water. Disposal of rejected brine from seawater reverse osmosis desalination plants causes major pollution problems and existing solutions are expensive. Recovery of valuable metals such as rubidium (Rb) after further concentration of the brine will lead to environmental and economic benefits. This project aims to develop a novel electrospun nanofibre membrane distillation membrane to economically concentrate the brine and to develop novel adsorbents and desorbents to recover the valuable Rb. It is expected that the concentration and recovery of Rb will lead to a sustainable way of handling the brine, as the concentration cost can be offset by the selling of Rb.Read moreRead less
Ultrathin membranes of novel structures for highly efficient water reuse. This project aims to develop a new generation of reverse osmosis membranes to enable significantly more efficient water reuse. The project expects to generate new knowledge in the area of membrane technology and wastewater reclamation using innovative designs of membrane structures and new techniques for membrane synthesis. Expected outcomes of the project include the development of highly permeable and high selective reve ....Ultrathin membranes of novel structures for highly efficient water reuse. This project aims to develop a new generation of reverse osmosis membranes to enable significantly more efficient water reuse. The project expects to generate new knowledge in the area of membrane technology and wastewater reclamation using innovative designs of membrane structures and new techniques for membrane synthesis. Expected outcomes of the project include the development of highly permeable and high selective reverse osmosis membranes. This project should provide significant benefits to water reuse by greatly improving product water quality and dramatically reducing its energy consumption by over 50 per cent, which in turn addresses the challenges of water scarcity and water-energy nexus.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