Multifunctional Porous Nanospheres Engineered Composite Membranes for Hydrogen and Methanol Fuel Cells. Increasing concerns about greenhouse gas emissions and dwindling petroleum supplies have driven the development and commercialisation of fuel cells. The development of novel nanocomposite membranes will possibly lead to the materials breakthrough necessary for advancing both hydrogen and methanol fuel cell technologies, significantly benefiting Australian clean energy supplies and in particul ....Multifunctional Porous Nanospheres Engineered Composite Membranes for Hydrogen and Methanol Fuel Cells. Increasing concerns about greenhouse gas emissions and dwindling petroleum supplies have driven the development and commercialisation of fuel cells. The development of novel nanocomposite membranes will possibly lead to the materials breakthrough necessary for advancing both hydrogen and methanol fuel cell technologies, significantly benefiting Australian clean energy supplies and in particular transport vehicles and portable devices. The synthesis strategies generated will be applicable to creating other functional nanoporous or nanocomposite materials for wider application. This project will also enhance the international reputation and impact of Australian research in the internationally focused fields of nanomaterials and fuel cell technology.Read moreRead less
Nanocomposite Mesoporous Materials for Gas Separations of Environmental Significance. The management of greenhouse and other acid gas emissions is vital to a sustainable future of both the economy and the ecosystem. This project will develop novel nano-materials for gas separation by tethering organic functional groups to the surface of porous inorganic supports. These materials offer the promise of combining the high selectivity and high capacity of liquid phase absorption systems with the rapi ....Nanocomposite Mesoporous Materials for Gas Separations of Environmental Significance. The management of greenhouse and other acid gas emissions is vital to a sustainable future of both the economy and the ecosystem. This project will develop novel nano-materials for gas separation by tethering organic functional groups to the surface of porous inorganic supports. These materials offer the promise of combining the high selectivity and high capacity of liquid phase absorption systems with the rapid transport rates of gas-solid adsorption systems. Success would open up several new possibilities for reengineering gas separation systems based on the use of these materials in solution, as solid phase adsorbents (pressure swing adsorption) and/or as permeselective gas membranes.Read moreRead less
NANOCOMPOSITE PROTON-CONDUCTING MEMBRANES FOR FUEL CELL APPLICATIONS. This project aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both ....NANOCOMPOSITE PROTON-CONDUCTING MEMBRANES FOR FUEL CELL APPLICATIONS. This project aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both hydrogen and methanol fuel cells, promising a revolutionary clean energy supply particularly for transport vehicles and mobile devices. The project addresses the synthesis and characterisation of nanostructured composite of proton-conducting nanoparticles, a key to high performance fuel cell membranes.Read moreRead less
Molecular Engineered Nanomaterials for Advanced Fuel Cells. This program aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to advanced fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both hy ....Molecular Engineered Nanomaterials for Advanced Fuel Cells. This program aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to advanced fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both hydrogen and methanol fuel cells, promising a revolutionary clean energy supply particularly for transport vehicles and mobile devices. This research advances the material science of nanostructured composite of proton-conducting nanoparticles, a key to high performance fuel cell membranes.Read moreRead less
Nano- and micro-scale engineering of MoS2-based catalyst for conversion of syngas to ethanol. Domestic production of ethanol to provide a 10% blend in petrol (E10) can be achieved from waste methane gas that Australia currently vents or flares to atmosphere. This project aims to develop a conversion process for making ethanol from syngas (the product of coal or methane gasification). Small scale, modularised plants would make ethanol locally to the methane emission source. The benefits of local ....Nano- and micro-scale engineering of MoS2-based catalyst for conversion of syngas to ethanol. Domestic production of ethanol to provide a 10% blend in petrol (E10) can be achieved from waste methane gas that Australia currently vents or flares to atmosphere. This project aims to develop a conversion process for making ethanol from syngas (the product of coal or methane gasification). Small scale, modularised plants would make ethanol locally to the methane emission source. The benefits of local E10 production would be a reduction in the oil trade deficit of $1 billion per year, $500 million per year in lower carbon imposts to industry and government, 25 million tonnes per year of reduced CO2e release to atmosphere and significantly improved urban air through reduced emissions from car transport, with attendant human health benefits.Read moreRead less
ARC Centre for Functional Nanomaterials. The Centre will consist of leading researchers from four Australian universities, four CSIRO divisions, and two US research centres. The vision is to position Australia as a world leader in nanomaterials science and technology. The Centre will involve nanoscale science for building functional nanostructures of materials at the molecular level. It aims to develop new methods and techniques for self-assembling and characterizing nanomaterials with tailorabl ....ARC Centre for Functional Nanomaterials. The Centre will consist of leading researchers from four Australian universities, four CSIRO divisions, and two US research centres. The vision is to position Australia as a world leader in nanomaterials science and technology. The Centre will involve nanoscale science for building functional nanostructures of materials at the molecular level. It aims to develop new methods and techniques for self-assembling and characterizing nanomaterials with tailorable properties. The outcomes will include leading-edge science, the development of human capital, and intellectual property in new materials and products for applications in clean energy, environmental, and health care industries.Read moreRead less