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Directional fluid-transfer in thin porous materials with gradient wettability through thickness. This project will further strengthen Australia's world leading position in advanced fibrous materials research. It will provide a new platform technology to develop self-driven unidirectional fluid-transfer fabrics and porous membranes for diverse applications in daily life, healthcare, defence and a number of industrial processes.
The development of flexible, graded plasma surface engineered coatings for superior interfacial performance. The next generation of intraocular lenses, medical devices to treat patients with cataracts, will be developed through application of advanced surface engineering technologies. These superior coated lenses will improve biocompatibility and function, leading to additional benefit for the forecasted 2.7 million Australians with cataracts by 2021.
Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the ....Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the key feed-stock of CO for sustainable use in hydrocarbon fuels, providing significant benefits in the reduction of greenhouse emissions.Read moreRead less
A highly sensitive and selective nano-engineered sensor for the online monitoring of mercury vapour emissions from harsh industrial processes. The Australian alumina and aluminium industries contribute over $11 billion export income annually. All refineries, except one, operate in rural areas and are the main economic drivers in these regions. In order to maintain the industry's commitment to reduce the environmental impact of its processes and remain economically sustainable, innovative technol ....A highly sensitive and selective nano-engineered sensor for the online monitoring of mercury vapour emissions from harsh industrial processes. The Australian alumina and aluminium industries contribute over $11 billion export income annually. All refineries, except one, operate in rural areas and are the main economic drivers in these regions. In order to maintain the industry's commitment to reduce the environmental impact of its processes and remain economically sustainable, innovative technologies are required to monitor mercury emissions. The aim of this project is to develop robust sensors, for online monitoring of mercury vapours, that operate under challenging industrial environments. This project will also provide excellent training for young researchers in established international industrial research groups, thereby meeting skill shortages in the Australian resource sector.Read moreRead less
Helium recovery from liquefied natural gas waste stream using nanoporous mxene materials. The waste streams from many liquefied natural gas (LNG) industries still contains valuable helium, a possible next mineral to sustain our economic growth. This project aims to efficiently separate helium from methane and nitrogen via the layered two dimensional materials. This project will seek to understand the assembling behaviour of these nano-sized Mxene flakes and their molecular sieving properties. Au ....Helium recovery from liquefied natural gas waste stream using nanoporous mxene materials. The waste streams from many liquefied natural gas (LNG) industries still contains valuable helium, a possible next mineral to sustain our economic growth. This project aims to efficiently separate helium from methane and nitrogen via the layered two dimensional materials. This project will seek to understand the assembling behaviour of these nano-sized Mxene flakes and their molecular sieving properties. Australia is playing a leading role in the global liquefied natural gas (LNG) production and trade. This project expects to further position Australia at the forefront of intellectual leadership in the field of gas processing and material development. This will have significant benefits, such as further improving these LNG projects economics by cost-effectively producing helium as a valuable by-product via advanced porous nano-materials.Read moreRead less
Advanced macromolecular engineering: novel approaches to self-directed assembly and vesicle formation. The aim of this project is to develop new approaches in nanotechnology for the preparation of well-defined polymeric particles. The research will result in the development of new methodology which has the potential to impact areas of commercial interest including those in the health-care sector.
Precision-Engineered Polymer Nanomaterials. Designing polymer nanoparticles that interact with or mimic biological systems represents a challenge in the field of polymer science. The project will address this challenge to deliver a quantitative and qualitative understanding linking synthetic materials and biological systems. Structurally perfect polymeric dendrimers, prepared using break through synthetic approaches and kinetic and computer modelling, are the ideal structure to introduce this fu ....Precision-Engineered Polymer Nanomaterials. Designing polymer nanoparticles that interact with or mimic biological systems represents a challenge in the field of polymer science. The project will address this challenge to deliver a quantitative and qualitative understanding linking synthetic materials and biological systems. Structurally perfect polymeric dendrimers, prepared using break through synthetic approaches and kinetic and computer modelling, are the ideal structure to introduce this function with predictable behaviour. The project will achieve tangible impacts for global communities and industries including the development of biomimetic nanodevices for smart drug delivery devices and peptide mimics.Read moreRead less
Development of nanostructured sensors for ultra-sensitive, label-free and selective detection of biological and chemical species. Outcomes will significantly advance the technical and fundamental understanding of sensor assembly and provide guidelines for developing and manufacturing nanostructured sensors, which is critical for next generation nanoscale sensing platforms for health care, medical diagnostics and chemical detection and Australia's emerging sensor industries.
Metal-air batteries with improved rate capability and safety for hearing applications. Hearing impairment affects on average 20% of the adult population in western society, with the impact being as high as 50% in older adults. Effective hearing devices require a significant amount of power, supplied by a battery, to support their function. Current batteries require very frequent replacement and represent a significant impediment to advances in the technology. This project will develop improved ....Metal-air batteries with improved rate capability and safety for hearing applications. Hearing impairment affects on average 20% of the adult population in western society, with the impact being as high as 50% in older adults. Effective hearing devices require a significant amount of power, supplied by a battery, to support their function. Current batteries require very frequent replacement and represent a significant impediment to advances in the technology. This project will develop improved energy and power density batteries which will lead to immediate implementation of more powerful signal processing algorithms, making hearing aids much more effective and appealing to the user. This, in turn, will improve recipient compliance and thus the quality of life for those with severe hearing impairment. Read moreRead less
Assembling multi-functional nanocomposites for carbon dioxide reduction by hybrid catalytic and photochemical approach. The overall aim of this project is to assemble multi-functional nanocomposites for carbon dioxide reduction by an integrated catalytic and photocatalytic approach. The issues of impending depletion of fossil fuel resources and irreversible climate change due to carbon dioxide emissions have stimulated research for the sustainable utilisation of carbon dioxide. In situ spectros ....Assembling multi-functional nanocomposites for carbon dioxide reduction by hybrid catalytic and photochemical approach. The overall aim of this project is to assemble multi-functional nanocomposites for carbon dioxide reduction by an integrated catalytic and photocatalytic approach. The issues of impending depletion of fossil fuel resources and irreversible climate change due to carbon dioxide emissions have stimulated research for the sustainable utilisation of carbon dioxide. In situ spectroscopic studies combined with theoretical calculations will be used to elucidate the underlying reaction mechanisms of the synergistic effects of photon and thermal reduction of carbon dioxide . The success of the proposed project will allow the reduction of carbon dioxide, generate a cheap energy source in the form of environmentally benign hydrocarbons and close the carbon loop. Read moreRead less