Epitaxial growth of Zn-VI/III-N nanowire-based structures for future device applications. This project, aiming for developing zinc and nitrogen epitaxial nanowires, addresses specific National Research Priorities in the areas of breakthrough science, frontier technology and advanced materials. Outcomes will significantly advance the understanding of the evolution of epitaxial nanowire structures and their demonstrated properties. This project will provide informative guidelines for designing, de ....Epitaxial growth of Zn-VI/III-N nanowire-based structures for future device applications. This project, aiming for developing zinc and nitrogen epitaxial nanowires, addresses specific National Research Priorities in the areas of breakthrough science, frontier technology and advanced materials. Outcomes will significantly advance the understanding of the evolution of epitaxial nanowire structures and their demonstrated properties. This project will provide informative guidelines for designing, developing and manufacturing nanowire-based nanostructures for future nanodevices and nanosystems, which is strategically important to Australia's emerging high-tech industries. This project will also enhance the international reputation and impact of Australian research in the internationally focused field of nanoscience and nanotechnology.Read moreRead less
Development of new membrane-electrode assemblies for low temperature fuel cells. New electrodes and electrolytes for low temperature fuel cells will herald in a new epoch in the hydrogen economy for Australia. The IP developed in this project will form the basis for new transportation systems that do not lead to chemical pollution in Australia's cities. The new materials and processing techniques will lead to cheaper and more efficient fuel cells, allowing their use in portable computers, small ....Development of new membrane-electrode assemblies for low temperature fuel cells. New electrodes and electrolytes for low temperature fuel cells will herald in a new epoch in the hydrogen economy for Australia. The IP developed in this project will form the basis for new transportation systems that do not lead to chemical pollution in Australia's cities. The new materials and processing techniques will lead to cheaper and more efficient fuel cells, allowing their use in portable computers, small electrical appliances, public transport and in private cars in about ten years. Read moreRead less
Special Research Initiatives - Grant ID: SR0354735
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Australian Network on Microelectronics, Optoelectronics and Microelectromechanical Systems. The Network will encompass semiconductor microelectronics, optoelectronics, sensors and microelectromechanical systems (MEMS). Fundamental research in these areas enables the technological advances that underpin rapidly developing industries such as information and telecommunications technologies, defence, aerospace, medicine, and remote sensing. Exciting challenges exist in designing new devices that exp ....Australian Network on Microelectronics, Optoelectronics and Microelectromechanical Systems. The Network will encompass semiconductor microelectronics, optoelectronics, sensors and microelectromechanical systems (MEMS). Fundamental research in these areas enables the technological advances that underpin rapidly developing industries such as information and telecommunications technologies, defence, aerospace, medicine, and remote sensing. Exciting challenges exist in designing new devices that exploit unique semiconductor systems and technologies. By sharing capabilities and resources (both capital and human), the network will enable the issues associated with such novel materials and devices to be addressed in a targeted manner. The network will also guarantee the ongoing future of research in the area by actively involving early career researchers and postgraduate students.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0667994
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
National Nanolithography Facility. Nanotechnology is expected to have a major impact on quality of life and global economy. It is predicted to generate revenues as big as the ICT sector in 20 years time. The National Nanolithography Facility will enhance the Australian capability in the field of nanoscale science and technology. This will enable Australian researchers to achieve major impacts in many areas of nanotechnology with a strong potential impact on industry sectors such as computers, ....National Nanolithography Facility. Nanotechnology is expected to have a major impact on quality of life and global economy. It is predicted to generate revenues as big as the ICT sector in 20 years time. The National Nanolithography Facility will enhance the Australian capability in the field of nanoscale science and technology. This will enable Australian researchers to achieve major impacts in many areas of nanotechnology with a strong potential impact on industry sectors such as computers, communications, defence, health, bio-security. This facility has the potential for developing new technologies of fundamental as well as applied interest.Read moreRead less
Investigation of novel magneto-optic materials exhibiting high Faraday figure of merit. Magneto-optical materials have a wide range of potential applications in consumer products, telecommunications and defence. Nanotechnologies based on these materials offer an even broader range of emerging applications. Understanding and participating in the development of magneto-optic technologies will therefore be critical to maintaining Australia's knowledge base and expertise in future technological adv ....Investigation of novel magneto-optic materials exhibiting high Faraday figure of merit. Magneto-optical materials have a wide range of potential applications in consumer products, telecommunications and defence. Nanotechnologies based on these materials offer an even broader range of emerging applications. Understanding and participating in the development of magneto-optic technologies will therefore be critical to maintaining Australia's knowledge base and expertise in future technological advances. Given the early stages of development of these technologies, Australia's expertise in material science and the patent rights held by Australian companies in this area, Australia has the opportunity to make major contributions to this field, and the potential to capitalise on the application of these technologies in niche markets.Read moreRead less
New multiplexed optical read-out technologies for micromachined cantilever sensor arrays. Passive sensing of chemical and biological agents is an essential capability in fields as diverse as national security, agriculture, mining and medicine. In many cases, generic sensing (e.g. are there pesticides present) as well as specific sensing (which pesticide) are both important. While sensors based on micro-electromechanical systems (MEMS) have shown extremely high performance at low cost, they have ....New multiplexed optical read-out technologies for micromachined cantilever sensor arrays. Passive sensing of chemical and biological agents is an essential capability in fields as diverse as national security, agriculture, mining and medicine. In many cases, generic sensing (e.g. are there pesticides present) as well as specific sensing (which pesticide) are both important. While sensors based on micro-electromechanical systems (MEMS) have shown extremely high performance at low cost, they have been limited to detection of a specific substance. Success in this project will make low cost generic MEMS-based sensors a reality, allowing, for the first time, wide-spread use of sensitive sensing systems in applications such as farming, container transport security, general medical practice and national security.Read moreRead less
SIMULATION OF DYE SENSITISED SOLAR CELL SYSTEMS: A ROUTE TO INCREASING MODULE AND ARRAY PERFORMANCE. This project will address the need to minimise electrical losses in arrays of dye-sensitised solar cells by undertaking development of a comprehensive electrical circuit model of the cells. The model will enable optimal design of the materials, geometry and interconnection of cells, maximum power delivery from cell arrays, and provide understanding of the impact of shading on the performance of ....SIMULATION OF DYE SENSITISED SOLAR CELL SYSTEMS: A ROUTE TO INCREASING MODULE AND ARRAY PERFORMANCE. This project will address the need to minimise electrical losses in arrays of dye-sensitised solar cells by undertaking development of a comprehensive electrical circuit model of the cells. The model will enable optimal design of the materials, geometry and interconnection of cells, maximum power delivery from cell arrays, and provide understanding of the impact of shading on the performance of arrays of dye-sensitised solar cells. This research will accelerate the development of environmentally friendly electricity generation in Australia, and contribute to employment and exports of technology.
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Development of High Frequency and High Power Density Magnetics and its Integrated Magnetic Circuit for Solar Renewable Energy Conversion Systems. The proposed project will result in theoretical and practical contributions to the field of high frequency (HF) magnetics and computational electromagnetics based computer modelling technologies for the power converter used in solar PV systems and high power density converters. The project will provide industry with several novel HF magnetic structures ....Development of High Frequency and High Power Density Magnetics and its Integrated Magnetic Circuit for Solar Renewable Energy Conversion Systems. The proposed project will result in theoretical and practical contributions to the field of high frequency (HF) magnetics and computational electromagnetics based computer modelling technologies for the power converter used in solar PV systems and high power density converters. The project will provide industry with several novel HF magnetic structures and the associated design methodology, and an innovative technology to industry and society with following major benefits: a) increased productivity and minimization of product risk, b) faster project management cycles through the use of cost-effective new design methodology, and c) an improved problem solving environment for scientific research and commercial applications.Read moreRead less
Understanding of nanostructures and magnetic properties of Ge-based diluted magnetic semiconductors for spintronic devices. The success of growing high-quality germanium-based diluted magnetic semiconductors will position Australian fundamental & applied research at the world forefront of magnetic semiconductors. This multi-disciplinary research will not only secure a number of high-impact publications in leading international journals, but also has the potential to generate patentable technolog ....Understanding of nanostructures and magnetic properties of Ge-based diluted magnetic semiconductors for spintronic devices. The success of growing high-quality germanium-based diluted magnetic semiconductors will position Australian fundamental & applied research at the world forefront of magnetic semiconductors. This multi-disciplinary research will not only secure a number of high-impact publications in leading international journals, but also has the potential to generate patentable technologies which might bring potential economic benefits to Australia. In addition, the project will strengthen the collaboration between Australian researchers and world-renowned scientists and will allow Australian researchers to access world-best fabrication facilities. All these will enhance the international competitive profile of Australia in the field of spintronics.Read moreRead less
Biomedical Applications of Self-Mixing Sensors based on Vertical-Cavity Surface-Emitting Laser Arrays. The Vertical-Cavity Surface-Emitting Laser (VCSEL) is a new optical device of choice for high speed optical data networks. We propose that this communications technology can be used as a platform to develop a completely new family of sensors ideally suited to medical monitoring. Specifically, we will develop VCSEL based technology for measurement of heart activity and sensing of blood flow in ....Biomedical Applications of Self-Mixing Sensors based on Vertical-Cavity Surface-Emitting Laser Arrays. The Vertical-Cavity Surface-Emitting Laser (VCSEL) is a new optical device of choice for high speed optical data networks. We propose that this communications technology can be used as a platform to develop a completely new family of sensors ideally suited to medical monitoring. Specifically, we will develop VCSEL based technology for measurement of heart activity and sensing of blood flow in skin and tissues. This will provide novel sensors for heart monitoring and imaging, and management of skin disorders (burns and cancer).Read moreRead less