Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561240
Funder
Australian Research Council
Funding Amount
$121,510.00
Summary
Combined reactor for the plasma-enhanced chemical vapour deposition (PECVD) of amorphous layers of silicon, silicon nitride and silicon oxide, and for Reactive Ion Etching. Our small, but very productive group (up to 30 publications per Discovery grant) has reached critical mass (8 people), and the acquisition of essential infrastructure is peremptory. Without the proposed plasma reactor our strong international impact (10 papers, one invited, at the 2003 world conference on photovoltaics) will ....Combined reactor for the plasma-enhanced chemical vapour deposition (PECVD) of amorphous layers of silicon, silicon nitride and silicon oxide, and for Reactive Ion Etching. Our small, but very productive group (up to 30 publications per Discovery grant) has reached critical mass (8 people), and the acquisition of essential infrastructure is peremptory. Without the proposed plasma reactor our strong international impact (10 papers, one invited, at the 2003 world conference on photovoltaics) will wane. This machine permits to deposit thin layers of silicon nitride and amorphous silicon and is a versatile tool for investigating silicon materials for photovoltaics and microelectronics. Such reactors have become an essential tool for silicon solar cell work. Most laboratories across the world have at least one, including UNSW, but access to the latter is impractical.Read moreRead less
Photonic structures for high efficiency, low cost solar cells. Photovoltaics is a non-polluting, environmentally sustainable way of converting sunlight directly to electricity. The reduction of cost is the most important issue in photovoltaic solar energy conversion. This project will lead to the development of solar cell structures and techniques that have the potential to significantly reduce the cost of thin film solar cells, which are the major contender for the lowest cost photovoltaic te ....Photonic structures for high efficiency, low cost solar cells. Photovoltaics is a non-polluting, environmentally sustainable way of converting sunlight directly to electricity. The reduction of cost is the most important issue in photovoltaic solar energy conversion. This project will lead to the development of solar cell structures and techniques that have the potential to significantly reduce the cost of thin film solar cells, which are the major contender for the lowest cost photovoltaic technology. If the cost of photovoltaics was sufficiently reduced it could have a major impact on reducing greenhouse gas emissions and pollution in Australia.Read moreRead less
ADVANCED PHYSICS AND CHARACTERISATION OF SILICON MATERIALS AND DEVICES. Silicon, the semiconductor material that has revolutionised modern society through Microelectronics, is also at the centre of Photovoltaics, the technology that permits harvesting the energy from the sun to improve the quality of life and sustain it beyond the limitations of fossil fuel resources. By improving our understanding of the fundamental properties of silicon and advancing the solar cell devices made from it, this p ....ADVANCED PHYSICS AND CHARACTERISATION OF SILICON MATERIALS AND DEVICES. Silicon, the semiconductor material that has revolutionised modern society through Microelectronics, is also at the centre of Photovoltaics, the technology that permits harvesting the energy from the sun to improve the quality of life and sustain it beyond the limitations of fossil fuel resources. By improving our understanding of the fundamental properties of silicon and advancing the solar cell devices made from it, this project aims to increase Australia's presence in the vast field of Microlectronics and maintain its leading position in solar energy technologies.Read moreRead less
Improving silicon grain boundaries by linking electronic material quality and device manufacturing conditions. This project develops our recent findings for improving silicon grain boundaries in electronic devices such as cheap solar cells, active matrix displays, thin-film transistors, etc. The performance of such devices and their applications have been limited mainly because no simple link between manufacturing conditions and device quality has been found. However, we recently verified a phys ....Improving silicon grain boundaries by linking electronic material quality and device manufacturing conditions. This project develops our recent findings for improving silicon grain boundaries in electronic devices such as cheap solar cells, active matrix displays, thin-film transistors, etc. The performance of such devices and their applications have been limited mainly because no simple link between manufacturing conditions and device quality has been found. However, we recently verified a physical model description of grain boundaries on a broad range of devices, and this allows us to find such a link and to address prevailing problems from a new perspective. This will improve both the understanding and the manufacturing of such devices.Read moreRead less
Power systems with diverse generation - implications, control and capability. This research will generate a systematic methodology to handle the impact of the renewable energy sources on the NSW power grid. It increases our understanding of the impact of climate change policies relating to mandatory targets for greenhouse gas reduction helping to build Australia’s research capacity in the national priority area of an environmentally sustainable Australia. The anticipated methodology can also be ....Power systems with diverse generation - implications, control and capability. This research will generate a systematic methodology to handle the impact of the renewable energy sources on the NSW power grid. It increases our understanding of the impact of climate change policies relating to mandatory targets for greenhouse gas reduction helping to build Australia’s research capacity in the national priority area of an environmentally sustainable Australia. The anticipated methodology can also be seen as protecting the security of power infrastructure as well. Maintaining a critical energy infrastructure protects our way of life and ensures ongoing social, economic and environmental well being of Australia.Read moreRead less
High efficiency III-V solar cells based on low-dimensional quantum confined heterostructures. There is no doubt that clean and sustainable solar energy is one of the most viable energy sources to address the issues of climate change, global warming and depletion of conventional energy sources. With the great advantages offered by quantum confined nanostructures and nanotechnology, this project may lead to substantial efficiency improvement of current III-V solar cells (already higher efficiency ....High efficiency III-V solar cells based on low-dimensional quantum confined heterostructures. There is no doubt that clean and sustainable solar energy is one of the most viable energy sources to address the issues of climate change, global warming and depletion of conventional energy sources. With the great advantages offered by quantum confined nanostructures and nanotechnology, this project may lead to substantial efficiency improvement of current III-V solar cells (already higher efficiency than Si solar cells), making great contribution to the society and Nation in the areas of science, technology, environment, and economy.Read moreRead less
New Directions in Silicon Solar Cell Technology. The fabrication of pure silicon is energy intensive, but solar cells can return 10 times more energy than is used to fabricate them. By investing in the development of silicon solar cells, Australia will develop a technology capable of encapsulating its vast coal resources within pure silicon. This has the potential to create an export market of clean energy and have an explosive effect on the growth of the local industry and skilled jobs.
Th ....New Directions in Silicon Solar Cell Technology. The fabrication of pure silicon is energy intensive, but solar cells can return 10 times more energy than is used to fabricate them. By investing in the development of silicon solar cells, Australia will develop a technology capable of encapsulating its vast coal resources within pure silicon. This has the potential to create an export market of clean energy and have an explosive effect on the growth of the local industry and skilled jobs.
This project will bolster the already prominent position of Australia in the field of photovoltaic solar energy by establishing collaborations with the top international organisations in the field. It will also coordinate efforts with all the main university research groups in the country. Read moreRead less
Spray-on Hydrogenated Films for Solar Cells. A successful project will contribute to a reduction in the cost of photovoltaic solar energy. This goal might be reached directly, via the development of spray-on hydrogenated films, or indirectly, through an improved knowledge of hydrogen passivation. Either way, the project will provide Australian Partner Investigator, Spark Solar, with a manufacturing edge over its global competitors. In so doing, it will support the burgeoning photovoltaic industr ....Spray-on Hydrogenated Films for Solar Cells. A successful project will contribute to a reduction in the cost of photovoltaic solar energy. This goal might be reached directly, via the development of spray-on hydrogenated films, or indirectly, through an improved knowledge of hydrogen passivation. Either way, the project will provide Australian Partner Investigator, Spark Solar, with a manufacturing edge over its global competitors. In so doing, it will support the burgeoning photovoltaic industry in Australia, providing jobs in manufacturing and research, and increasing the viability of photovoltaic energy as an alternative to fossil fuels. The project will also help keep Australia at the forefront of advances in photovoltaics and semiconductors.Read moreRead less
Investigation of P Type Emitters for Future Generation Photovoltaics. The overseas market for photovoltaic panels is large and rapidly expanding - it is expected to grow six-fold over the next decade, to nearly US$10 billion per annum. Australia is well placed to capture a significant share of this market, creating employment and export earnings. The project is expected to make a significant contribution to the development of a vibrant and highly competitive photovoltaics industry in Australia, ....Investigation of P Type Emitters for Future Generation Photovoltaics. The overseas market for photovoltaic panels is large and rapidly expanding - it is expected to grow six-fold over the next decade, to nearly US$10 billion per annum. Australia is well placed to capture a significant share of this market, creating employment and export earnings. The project is expected to make a significant contribution to the development of a vibrant and highly competitive photovoltaics industry in Australia, since the results of the research are expected to lead to improved manufacturing processes. In addition, photovoltaics will be a key technology to reduce greenhouse gas emissions and thus mitigate the magnitude and severity of the effects of global warming. Read moreRead less
High Temperature Silicon Nitride for Improved Silicon Photovoltaics. The project is expected to make a significant contribution to the development of a vibrant and highly competitive photovoltaics industry in Australia, since the results of the research are expected to lead to improved manufacturing processes. A strong photovoltaics industry will lead to the creation of significant numbers of jobs and export earnings. There is a large and rapidly expanding overseas market for solar panels. In a ....High Temperature Silicon Nitride for Improved Silicon Photovoltaics. The project is expected to make a significant contribution to the development of a vibrant and highly competitive photovoltaics industry in Australia, since the results of the research are expected to lead to improved manufacturing processes. A strong photovoltaics industry will lead to the creation of significant numbers of jobs and export earnings. There is a large and rapidly expanding overseas market for solar panels. In addition, the large scale deployment of photovoltaic systems will help to reduce greenhouse gas emissions and thus mitigate the magnitude and severity of the effects of global warming. Read moreRead less