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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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560662
Funder
Australian Research Council
Funding Amount
$204,157.00
Summary
Flow Diagnostics Facility for Microstructured Systems. This Project will establish Australia's only world-class facility for the interrogation of steady and fluctuating flows in microstructured components, enabling detailed characterisation of the flow patterns and velocities that occur in single phase and multiphase flows in miniature devices. Such devices are currently being developed by the Chief Investigators in the area of microreactor technology and chemical process intensification, in mic ....Flow Diagnostics Facility for Microstructured Systems. This Project will establish Australia's only world-class facility for the interrogation of steady and fluctuating flows in microstructured components, enabling detailed characterisation of the flow patterns and velocities that occur in single phase and multiphase flows in miniature devices. Such devices are currently being developed by the Chief Investigators in the area of microreactor technology and chemical process intensification, in microelectromechanical systems (MEMS), and in high efficiency membrane separation systems. The new Facility will enable them and others to enhance their research through visualisation and quantification of flow behaviour at the scale of a few micrometres.Read moreRead less
Development of Superflux Carbon Nanotube Membranes for Gas Separation. The project seeks to develop gas separation membranes displaying superfluxes - throughputs 10 to 100 times higher than current systems, with lower operating costs. There is compelling evidence that very high flow rates are achievable and they have been shown for single gas transport. Theory predicts that highly selective separations are possible, but this has not yet been experimentally shown - a key outcome from this proje ....Development of Superflux Carbon Nanotube Membranes for Gas Separation. The project seeks to develop gas separation membranes displaying superfluxes - throughputs 10 to 100 times higher than current systems, with lower operating costs. There is compelling evidence that very high flow rates are achievable and they have been shown for single gas transport. Theory predicts that highly selective separations are possible, but this has not yet been experimentally shown - a key outcome from this project. The applications are widespread and include separation of carbon dioxide from power station flue gas for sequestration, purification of natural gas and provision of pure component gases such as oxygen and nitrogen amongst others.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
Synthesis of Unique Mesoporous Graphitic Carbons and their Application to Fundamental Problems in Adsorption Science. The development of synthesis techniques to create porous graphitic carbons with highly ordered pore structures, easily accessible pore volume and good electrical conductivity can underpin technological advancements in many industrial applications such as energy storage, removal of pollutants from exhaust streams, direct-methanol fuel cells and lithium ion batteries. Techniques de ....Synthesis of Unique Mesoporous Graphitic Carbons and their Application to Fundamental Problems in Adsorption Science. The development of synthesis techniques to create porous graphitic carbons with highly ordered pore structures, easily accessible pore volume and good electrical conductivity can underpin technological advancements in many industrial applications such as energy storage, removal of pollutants from exhaust streams, direct-methanol fuel cells and lithium ion batteries. Techniques developed in this project are also applicable to creating other materials important to advanced sensors and optoelectronics. The fundamental study of water adsorption and hysteresis using these carbons will help us create better models for adsorption. This will underpin theoretical studies, characterisation and optimisation of carbon materials into the future. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775550
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Characterisation Equipment for Advanced Gas Separation Applications. The proposed research will lead to the synthesis of new advanced materials capable of performing new and existing separations more efficiently than previous methods. We therefore expect the new materials to directly benefit the community through improved removal and recovery of a wide range of pollutants which would otherwise enter the environment. This research is directly aligned to the National Research Priority of Frontie ....Characterisation Equipment for Advanced Gas Separation Applications. The proposed research will lead to the synthesis of new advanced materials capable of performing new and existing separations more efficiently than previous methods. We therefore expect the new materials to directly benefit the community through improved removal and recovery of a wide range of pollutants which would otherwise enter the environment. This research is directly aligned to the National Research Priority of Frontier Technologies for Building and Transforming Australian Industries: Advanced Materials.Read moreRead less
Novel nanostructured alloy membranes for hydrogen permeation: Advanced materials technology for renewable energy. Hydrogen purification by alloy membranes is a key technology in maintaining the greenhouse gas emission low while using the fossil fuels including coal for energy generation. However, the alloys currently available for the membrane separation are mostly based on a costly precious metal palladium, making the application of the technology limited. The proposed non-equilibrium material ....Novel nanostructured alloy membranes for hydrogen permeation: Advanced materials technology for renewable energy. Hydrogen purification by alloy membranes is a key technology in maintaining the greenhouse gas emission low while using the fossil fuels including coal for energy generation. However, the alloys currently available for the membrane separation are mostly based on a costly precious metal palladium, making the application of the technology limited. The proposed non-equilibrium material processing will enable us to fabricate novel nanocomposite niobium-based alloys to which excellent hydrogen permeation characteristics are expected with high economic viability. Successful development of the proposed alloys could enhance the competitiveness of the Australian coal industry worldwide.Read moreRead less
Advanced hierarchical materials for separation applications. The proposed project represents an international collaboration between Monash University and Fudan University and builds on the research strengths within these two Institutions in nano-materials research and applications. The proposed research will lead to a new class of materials for use in the chemical and biological industries, making their operation more efficient and permitting new separations to be performed. The research will ....Advanced hierarchical materials for separation applications. The proposed project represents an international collaboration between Monash University and Fudan University and builds on the research strengths within these two Institutions in nano-materials research and applications. The proposed research will lead to a new class of materials for use in the chemical and biological industries, making their operation more efficient and permitting new separations to be performed. The research will also pioneer new techniques for use in nano-engineering materials and falls within one of Australia's National Research Priorities: Frontier Technologies for Building and Transforming Australian Industries.Read moreRead less
Novel Synthesis and Bio-applications of Functional Macroporous Ordered Siliceous Foams. This project will lead to advances in materials science and nanotechnology, providing high efficiency separation and purification for viruses or plasmid deoxyribonucleic acid (DNA), which are important in modern gene engineering for the treatment of genetic and acquired diseases. Application benefits also include developing a new protocol in the detection of trace amount proteins, which will afford a signific ....Novel Synthesis and Bio-applications of Functional Macroporous Ordered Siliceous Foams. This project will lead to advances in materials science and nanotechnology, providing high efficiency separation and purification for viruses or plasmid deoxyribonucleic acid (DNA), which are important in modern gene engineering for the treatment of genetic and acquired diseases. Application benefits also include developing a new protocol in the detection of trace amount proteins, which will afford a significant improvement in diverse fields such as health care. Through this project, novel macroporous materials will be fabricated using an economically and environmentally sustainable approach. These new materials will have unique structures and properties compared to conventional macroporous materials, advancing Australia's intellectual position in this discipline.Read moreRead less
Fundamental Characterization of Adsorption of Simple to Complex Fluids on Carbon Black and in Carbon Pores. The outcome of this project will help designing engineers with a molecular simulation model for adsorption of simple to complex fluids commonly used in industries. The success of this project translates to a significant saving because it requires minimum effort in experimentation.