Immune-imprinting nanoparticles (iNPs). This research promises new classes of immune-imprinting, biodegradable nanoparticles (iNPs) with anti-inflammatory properties. The engineering of such particles requires fundamental understanding of their properties that enable specific cellular interactions to regulate immunity with new anti-inflammatory pathways. For pulmonary delivery, spray-dried amino acid microspheres with tailored surfaces as carriers can be generated using the innovative microfluid ....Immune-imprinting nanoparticles (iNPs). This research promises new classes of immune-imprinting, biodegradable nanoparticles (iNPs) with anti-inflammatory properties. The engineering of such particles requires fundamental understanding of their properties that enable specific cellular interactions to regulate immunity with new anti-inflammatory pathways. For pulmonary delivery, spray-dried amino acid microspheres with tailored surfaces as carriers can be generated using the innovative microfluidic drying approach. The potential applications of iNPs are wide-ranging and are not restricted to pulmonary targeting. The potential commercial implications for Australia's emerging biopharmaceutical industry are substantial.Read moreRead less
Designing the surface and structural properties of MFI zeolite membranes for low energy ion-selective desalination. Desalination is being established in response to climate change and growing demands on existing supplies. Fresh water from infinitely abundant ocean sources using little energy input will benefit communities by providing affordably a vital resource with minimal greenhouse gas emissions. Fresh water from current desalination costs $2 per kl, being a major expense for a vital resourc ....Designing the surface and structural properties of MFI zeolite membranes for low energy ion-selective desalination. Desalination is being established in response to climate change and growing demands on existing supplies. Fresh water from infinitely abundant ocean sources using little energy input will benefit communities by providing affordably a vital resource with minimal greenhouse gas emissions. Fresh water from current desalination costs $2 per kl, being a major expense for a vital resource normally $0.2 per kl. As energy input accounts for half of the desalination cost, the smart ion-selective membrane to be developed in this project has the capability to reduce desalinated water price by 50%. Such an advancement derived from fundamental material properties is a novel contribution to both science and membrane desalinationRead moreRead less
The Permeation of Water through Industrial Membrane Systems. This project aims to understand the permeation of water through commercially relevant non-porous polymeric membranes. Permeation, solubility and diffusivity will be studied in the vicinity of the glass transition temperature to elucidate the changes in free volume that occur through this transition. Non-linear concentration gradients due to anisotropic swelling will be probed using novel laminated membrane systems. Water clustering wil ....The Permeation of Water through Industrial Membrane Systems. This project aims to understand the permeation of water through commercially relevant non-porous polymeric membranes. Permeation, solubility and diffusivity will be studied in the vicinity of the glass transition temperature to elucidate the changes in free volume that occur through this transition. Non-linear concentration gradients due to anisotropic swelling will be probed using novel laminated membrane systems. Water clustering will be evaluated by Fourier transform infrared spectroscopy and nuclear magnetic resonance. Results are proposed to be used to build a new phenomenological model of water permeation that can be used directly by engineers in the design of industrial membrane systems.Read moreRead less
Influence of Impurities in Commercial Solvent Extraction Processes. This project directly supports the solvent extraction industry in Australia. This industry is responsible for generating in excess of $600M annually of export earnings for Australia. This type of technology can be applied in the recovery of base metals such as coper, nickel, cobalt, etc and in the environmental area for the clean up of heavy metals from waste water. Solvent extraction has the advantage of high selectivity that ....Influence of Impurities in Commercial Solvent Extraction Processes. This project directly supports the solvent extraction industry in Australia. This industry is responsible for generating in excess of $600M annually of export earnings for Australia. This type of technology can be applied in the recovery of base metals such as coper, nickel, cobalt, etc and in the environmental area for the clean up of heavy metals from waste water. Solvent extraction has the advantage of high selectivity that enables metals to be recovered and recycled, thus reducing the wastage of these metals in, for example, the chromium plating process.Read moreRead less
Novel conversion process for carbon dioxide to chemicals. This project aims to develop a novel sorption enhanced material and system to convert atmospheric carbon dioxide (CO2) to methanol. Climate change is one of the primary long-term problems confronting humankind today. Since the production of CO2 through burning fossil fuel is far greater than the current usage of CO2, there is currently little alternative to storage. As a result, there is concerted effort globally to develop alternate use ....Novel conversion process for carbon dioxide to chemicals. This project aims to develop a novel sorption enhanced material and system to convert atmospheric carbon dioxide (CO2) to methanol. Climate change is one of the primary long-term problems confronting humankind today. Since the production of CO2 through burning fossil fuel is far greater than the current usage of CO2, there is currently little alternative to storage. As a result, there is concerted effort globally to develop alternate uses and conversion technologies for CO2. This project will help further this goal.Read moreRead less
Development of nanoporous materials for capture and release of oxygen. This project aims to develop new materials to make lighter, more efficient oxygen concentrators. The project will combine materials that can capture oxygen with particles that can be magnetically heated, making it possible to release the oxygen rapidly and efficiently when needed. Expected outcomes from this project include new composite materials and better understanding of how gases are trapped and released within composite ....Development of nanoporous materials for capture and release of oxygen. This project aims to develop new materials to make lighter, more efficient oxygen concentrators. The project will combine materials that can capture oxygen with particles that can be magnetically heated, making it possible to release the oxygen rapidly and efficiently when needed. Expected outcomes from this project include new composite materials and better understanding of how gases are trapped and released within composite materials. Benefits from this project may include oxygen concentrators that are more portable and have longer battery life, both with industrial and medical applications.Read moreRead less
Zeolitic Nanoflake-Polymer Composite Membranes for Low Energy Desalination. The desalination of seawater is becoming an important source of drinking water for Australia. The current desalination process using polymer membranes is energy-intensive. The proposed project will contribute to the development of low energy desalination technology by advancing membrane design and fabrication techniques. The use of zeolitic nanoflake-polymer composite membranes developed in this project is expected to su ....Zeolitic Nanoflake-Polymer Composite Membranes for Low Energy Desalination. The desalination of seawater is becoming an important source of drinking water for Australia. The current desalination process using polymer membranes is energy-intensive. The proposed project will contribute to the development of low energy desalination technology by advancing membrane design and fabrication techniques. The use of zeolitic nanoflake-polymer composite membranes developed in this project is expected to substantially reduce energy consumption in the desalination process. This research will produce important economic and environmental benefits by developing a green technology for fresh water production and water treatment for power generation, irrigation and other industrial uses.Read moreRead less
Overcoming performance limiting chemistries in membrane distillation. This project aims to study performance limiting chemistries associated with fouling of solution-borne components on membrane surfaces that cause critical vapour pressure loss. Membrane distillation could be used for sustainable resource recovery, but no research has overcome the total loss of membrane water flux when removing water from saturated solutions where the critical resource recovery function occurs. This project will ....Overcoming performance limiting chemistries in membrane distillation. This project aims to study performance limiting chemistries associated with fouling of solution-borne components on membrane surfaces that cause critical vapour pressure loss. Membrane distillation could be used for sustainable resource recovery, but no research has overcome the total loss of membrane water flux when removing water from saturated solutions where the critical resource recovery function occurs. This project will characterise the physical and chemical properties of the flux limiting solid on the membrane surface, and the role of membrane chemistry and functional conditions in overcoming this limit. The outcomes of the work will provide innovative sustainable solutions to recover valuable products from current wastes.Read moreRead less
Next generation gas separations via innovative adsorption technologies. This project aims to develop new gas separation technologies that combine novel materials and pressure swing adsorption cycles to deliver inexpensive industrial processes capable of both high recovery and high purity products. The project will advance our ability to manipulate the phenomenon of regulated guest admission into microporous materials, and integrate such materials within new types of dual-reflux adsorption cycles ....Next generation gas separations via innovative adsorption technologies. This project aims to develop new gas separation technologies that combine novel materials and pressure swing adsorption cycles to deliver inexpensive industrial processes capable of both high recovery and high purity products. The project will advance our ability to manipulate the phenomenon of regulated guest admission into microporous materials, and integrate such materials within new types of dual-reflux adsorption cycles that deliver multiple refined gas products. Successful implementation of these industrial developments will increase Australia's access to cheap supplies of natural gas, encourage the broader use of biomass, lower the carbon emissions of industrial processes, and efficiently recover high-value compounds only present at trace concentrations.Read moreRead less
Regulating guest transport in microporous materials by electric field. This project aims to address the fundamentals and applications of regulating micropore accessibility. It has long been known that some highly adsorbing molecular sieves suddenly become inaccessible to gases below certain temperatures. Following a recent breakthrough in elucidating the mechanism of such temperature-regulated guest admission, this project will explore electrical regulation of micropore accessibility in conjunct ....Regulating guest transport in microporous materials by electric field. This project aims to address the fundamentals and applications of regulating micropore accessibility. It has long been known that some highly adsorbing molecular sieves suddenly become inaccessible to gases below certain temperatures. Following a recent breakthrough in elucidating the mechanism of such temperature-regulated guest admission, this project will explore electrical regulation of micropore accessibility in conjunction with developing new mechanisms, materials, and control tools for applications, including tunable molecular sieves, valves and gas encapsulation devices. The outcomes of this project will generate new knowledge in the active manipulation of the admission and release of guest molecules in/out of microporous materials, and establish new expertise and capabilities that can advance gas separation, storage and sensing technologies. It is expected that this project will contribute to the long term benefit in low emission energy supplies and Australia's natural gas industry, improve the separation efficiency of our chemical industry, and boost the development of the hydrogen economy.Read moreRead less