Efficient photovoltaic concentrator receivers utilising commercial non-concentrator solar cells. The development of low-cost photovoltaic concentrator systems will allow the large scale depoyment of these systems, both in Australia and overseas. The current size of this market is several hundred MW of electricity per year, and growing rapidly. This will have both environmental benefits (though reduced greenhouse gas emissions)as well as economic and social benefits - through the creation of empo ....Efficient photovoltaic concentrator receivers utilising commercial non-concentrator solar cells. The development of low-cost photovoltaic concentrator systems will allow the large scale depoyment of these systems, both in Australia and overseas. The current size of this market is several hundred MW of electricity per year, and growing rapidly. This will have both environmental benefits (though reduced greenhouse gas emissions)as well as economic and social benefits - through the creation of empoyment opportunities in PV manufacturing and the generation of export earnings. It could be of particular benefit to remote communities requiring reliable, low cost off-grid power generation.Read moreRead less
Minimising charge carrier recombination at silicon surfaces with improved dielectric coatings. The project will help to develop a vibrant PV industry in Australia, creating substantial employment opportunities. Spark Solar - one of the project partners - is the first dedicated PV manufacturer in Australia. There is a large and rapidly expanding overseas export market for solar panels. In addition, the large scale deployment of photovoltaic systems will help to reduce greenhouse gas emissions and ....Minimising charge carrier recombination at silicon surfaces with improved dielectric coatings. The project will help to develop a vibrant PV industry in Australia, creating substantial employment opportunities. Spark Solar - one of the project partners - is the first dedicated PV manufacturer in Australia. There is a large and rapidly expanding overseas export 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
The development of inexpensive negatively charged films to increase the efficiency of commercial solar cells. This project aims to reduce the cost of solar electricity by developing inexpensive, negatively charged dielectric films. When deposited on the surfaces of commercial solar cells, these films will significantly increase cell efficiency, thereby producing more power from a given area.
Enhancing the Understanding and Performance of Passivating TiO2 Coatings for Photovoltaic Devices. Titanium dioxide (TiO2) has been widely used as an antireflection coating in the silicon (Si) photovoltaics industry as it exhibits excellent optical properties and low deposition cost. However, recently manufacturers have been turning to alternatives such as hydrogenated silicon nitride coatings that exhibit greatly improved electronic properties, but cost 4 - 10 times more to deposit. This proj ....Enhancing the Understanding and Performance of Passivating TiO2 Coatings for Photovoltaic Devices. Titanium dioxide (TiO2) has been widely used as an antireflection coating in the silicon (Si) photovoltaics industry as it exhibits excellent optical properties and low deposition cost. However, recently manufacturers have been turning to alternatives such as hydrogenated silicon nitride coatings that exhibit greatly improved electronic properties, but cost 4 - 10 times more to deposit. This project seeks to understand the fundamental limitations behind the poor surface passivation afforded by TiO2 to a Si wafer, and subsequently develop a passivating TiO2 coating that can reduce the cost of electricity generated by Si solar cells.Read moreRead less
Overcoming performance limitations in multicrystalline silicon solar cells. This project aims to address the major impediments to improved efficiency of multicrystalline silicon solar cells, the most prevalent in industry today. Three key areas have been identified: understanding the fundamental source of carrier recombination in this material, the application of plasma silicon nitride to reducing this recombination, and developing a suitable technique for texturing the front surface of the cell ....Overcoming performance limitations in multicrystalline silicon solar cells. This project aims to address the major impediments to improved efficiency of multicrystalline silicon solar cells, the most prevalent in industry today. Three key areas have been identified: understanding the fundamental source of carrier recombination in this material, the application of plasma silicon nitride to reducing this recombination, and developing a suitable technique for texturing the front surface of the cells. By using novel, advanced techniques to gain a deeper physical understanding of these issues, it will be possible to develop new, cost-effective processes that improve efficiency and are applicable in industry.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
Efficient PV-Thermal Micro-concentrator. Australia must reduce its dependence on carbon sources for electricity, heating, and cooling. The PV-thermal hybrid micro-concentrator development will deliver a light-weight, low-profile, cost-effective system that can be installed in almost any situation, with versatile output that can deliver electricity at grid parity as well as providing water heating, space heating, industrial process heat, and solar cooling capabilities. The nation will benefit thr ....Efficient PV-Thermal Micro-concentrator. Australia must reduce its dependence on carbon sources for electricity, heating, and cooling. The PV-thermal hybrid micro-concentrator development will deliver a light-weight, low-profile, cost-effective system that can be installed in almost any situation, with versatile output that can deliver electricity at grid parity as well as providing water heating, space heating, industrial process heat, and solar cooling capabilities. The nation will benefit through enhanced energy independence, international research recognition, and reduced greenhouse gas emissions. Further, successful commercialisation of this technology will enhance Australia's research standing and provide a good royalty income that will fund future research and development.Read moreRead less
Advanced Sliver Solar Cells. The expected outcome of the proposed research is the development of second generation Sliver solar cell technology, encouraging large commercial impact, which would be of substantial benefit to Australia in terms of export income and employment. Origin Energy has committed >$60 million to the development and commercialisation of the first generation Sliver cell technology. Substantial further commercial investment is expected during scale-up for full scale manufactur ....Advanced Sliver Solar Cells. The expected outcome of the proposed research is the development of second generation Sliver solar cell technology, encouraging large commercial impact, which would be of substantial benefit to Australia in terms of export income and employment. Origin Energy has committed >$60 million to the development and commercialisation of the first generation Sliver cell technology. Substantial further commercial investment is expected during scale-up for full scale manufacturing.
Successful implementation of technology developed during the research will result in the displacement of fossil fuel technologies and corresponding greenhouse gas emissions reduction, assisting Government in its objective to make major cuts to greenhouse gas emissions.
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A 60% efficient solar microconcentrator for electricity and hot water. The aim of this project is to develop a microconcentrator for deployment on house roofs that will produce both solar hot water and solar electricity with a combined efficiency above 60%. The system will have a low profile and will be nearly invisible from the street. The system will track the sun. Concentration will be accomplished by a mixture of refraction and reflection. About 20% of the sunlight will be converted to elect ....A 60% efficient solar microconcentrator for electricity and hot water. The aim of this project is to develop a microconcentrator for deployment on house roofs that will produce both solar hot water and solar electricity with a combined efficiency above 60%. The system will have a low profile and will be nearly invisible from the street. The system will track the sun. Concentration will be accomplished by a mixture of refraction and reflection. About 20% of the sunlight will be converted to electricity using lines of tiny solar cells, with the balance being converted to heat which is removed by cooling fluid and stored in hot water tanks.Read moreRead less
Next generation, very high efficiency thin silicon cells. A new type of thin silicon solar cell, with an efficiency potential of 21% or greater, is to be developed and characterized.
These cells should be cheaper, and have better efficiency, power to weight ratio and radiation tolerance than existing commercial silicon solar cells opening interesting possible applications. Novel solar cell designs and associated interconnection and encapsulation schemes for the cells suitable for space and hi ....Next generation, very high efficiency thin silicon cells. A new type of thin silicon solar cell, with an efficiency potential of 21% or greater, is to be developed and characterized.
These cells should be cheaper, and have better efficiency, power to weight ratio and radiation tolerance than existing commercial silicon solar cells opening interesting possible applications. Novel solar cell designs and associated interconnection and encapsulation schemes for the cells suitable for space and high altitude aircraft applications superior to existing technologies are expected to be developed. This should lead to a new, internationally competitive Australian industry.
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