A novel air-cooled fuel cell system. This project presents a novel cooling technology for fuel cell systems. This new design will not only save up to 50 per cent of the material cost but also leads to 20 per cent less fuel consumption compared to the existing fuel cells. This can save us billions of dollars per year with profound impact on our nation's carbon-emission-free alternative energy sources.
Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all ox ....Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all oxide-based PEMFC technology using a recently developed sintered and heteropolyacid functionalised mesoporous silica membrane. The utilisation of all-oxide-PEMFCs using non-precious metal catalysts is expected to significantly enhance the power density, reduce costs, and enhance the commercial viability of PEMFC technologies.Read moreRead less
Development of High Performance Nanostructured (Bi, Sb)2Te3 Nanomaterials. The direct energy conversion between heat and electricity, based on thermoelectric effects without moving parts, has been considered as a green and sustainable solution to the global energy dilemma. This project aims to develop novel band-engineered (Bi, Sb)2Te3 nanomaterials for high-efficiency energy conversion using novel microwave assisted wet chemistry approach, coupled with nanostructure and band engineering strateg ....Development of High Performance Nanostructured (Bi, Sb)2Te3 Nanomaterials. The direct energy conversion between heat and electricity, based on thermoelectric effects without moving parts, has been considered as a green and sustainable solution to the global energy dilemma. This project aims to develop novel band-engineered (Bi, Sb)2Te3 nanomaterials for high-efficiency energy conversion using novel microwave assisted wet chemistry approach, coupled with nanostructure and band engineering strategies. The key breakthrough is to design high performance (Bi, Sb)2Te3 thermoelectrics for satisfying the high efficiency solid-state devices. The expected outcomes will lead to an innovative technology that waste heat recovery and refrigeration, which will place Australia at the forefront of practical energy technologies.Read moreRead less
New mesoporous materials for use in high temperature proton exchange fuel cell membranes. A novel high temperature proton exchange membrane based on heteropolyacid (HPA) functionalised mesoporous silica will be developed. This research into the fundamental materials science of novel proton exchange membranes is expected to impact significantly on the advancement and commercialisation of portable fuel cell devices.
Controlling the adhesome to regulate cell fate on biomaterials. Mesenchymal stem cell-based tissue engineering practices are hampered worldwide by the lack of appreciation and understanding of the matrix-mediated cues that must be provided during adhesion and spreading to drive cells to definitive tissue end points. This project will address these knowledge deficiencies by combining high throughput array technologies, a set of tailorable self-assembling biomaterials and real-time biosensors to r ....Controlling the adhesome to regulate cell fate on biomaterials. Mesenchymal stem cell-based tissue engineering practices are hampered worldwide by the lack of appreciation and understanding of the matrix-mediated cues that must be provided during adhesion and spreading to drive cells to definitive tissue end points. This project will address these knowledge deficiencies by combining high throughput array technologies, a set of tailorable self-assembling biomaterials and real-time biosensors to rapidly, at high resolution, elucidate how mechanotransductive cues determine the fate choice of mesenchymal stem cells, and furthermore, how to manipulate them with smart biomaterial design to achieve desired outcomes for tissue engineering. Read moreRead less
Towards energy-efficient lighting based on light-emitting diodes: the role of silicon carbide grown on Si Wafers. This project will investigate a potential solution to the problems of cost and quality of light-emitting diodes for solid-state lighting. The expected outcome is knowledge to underpin future development of solid-state lighting that is suitable for a wide replacement of the much less efficient and effective incandescent bulbs and fluorescent tubes.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100200
Funder
Australian Research Council
Funding Amount
$270,427.00
Summary
AutoStem: a high performance, automated stem cell bioengineering facility. This project aims to establish an automated stem cell bioengineering ("AutoStem") facility that will enable critical insights into the molecular mechanisms that underly the loss in stem cell function and tissue homeostasis as we age. The AutoStem facility expects to lead to the discovery of the key drivers of stem cell ageing and the development of novel technological solutions to maintain tissue function with age. The o ....AutoStem: a high performance, automated stem cell bioengineering facility. This project aims to establish an automated stem cell bioengineering ("AutoStem") facility that will enable critical insights into the molecular mechanisms that underly the loss in stem cell function and tissue homeostasis as we age. The AutoStem facility expects to lead to the discovery of the key drivers of stem cell ageing and the development of novel technological solutions to maintain tissue function with age. The outcomes produced from the AutoStem facility will have significant economic and social benefits in enabling healthy ageing and increased productivity for an ageing Australia.Read moreRead less
Silicon-Carbide Switches for Post-Silicon Efficiency of Power Electronics. The aim of this project is to create a prototype of a silicon carbide (SiC)-based power-electronic switch for improved energy efficiency and reduced size of power-electronic circuits, well beyond the theoretical limits of silicon technology. Until very recently, the dominant controlled switch in electronics could only be implemented as a silicon transistor. A new method of electronic passivation of SiC surfaces has enable ....Silicon-Carbide Switches for Post-Silicon Efficiency of Power Electronics. The aim of this project is to create a prototype of a silicon carbide (SiC)-based power-electronic switch for improved energy efficiency and reduced size of power-electronic circuits, well beyond the theoretical limits of silicon technology. Until very recently, the dominant controlled switch in electronics could only be implemented as a silicon transistor. A new method of electronic passivation of SiC surfaces has enabled the recent commercialisation of SiC transistors. It is expected that the material advantages of SiC can be fully exploited by a new device structure and a new fabrication process.Read moreRead less