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Atomisation and Combustion Physics of Australian Bio-oils. Australia is highly dependent on fossil fuels for energy production and transport, and this dependence is growing. Wide spread substitution of liquid hydrocarbon fuels by indigenous renewable bio-oil has the potential to improve Australian's energy outlook and assist in reaching greenhouse gas targets. Understanding the interrelationships between the physical and chemical properties of bio-oil, its atomisation, droplet formation and com ....Atomisation and Combustion Physics of Australian Bio-oils. Australia is highly dependent on fossil fuels for energy production and transport, and this dependence is growing. Wide spread substitution of liquid hydrocarbon fuels by indigenous renewable bio-oil has the potential to improve Australian's energy outlook and assist in reaching greenhouse gas targets. Understanding the interrelationships between the physical and chemical properties of bio-oil, its atomisation, droplet formation and combustion physics is fundamental to the delivery of an efficient and reliable combustion process using this fuel. Measurements using laser based diagnostics of the atomisation flow, droplet formation and combustion process will provide the experimental data to understand this complex interrelationship.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560683
Funder
Australian Research Council
Funding Amount
$321,953.00
Summary
A furnace stack for advanced photovoltaic, photonic and microfabrication applications. Advanced silicon photovoltaic, photonic, optoelectronic and micro-electromechanical devices require state of the art processing equipment for the deposition of thin dielectric films and for controlled doping of the devices. Key techniques include the deposition of stoichiometric and silicon rich silicon nitride and silicon dioxide films, and the controlled wafer doping with boron and phosphorus. A state of the ....A furnace stack for advanced photovoltaic, photonic and microfabrication applications. Advanced silicon photovoltaic, photonic, optoelectronic and micro-electromechanical devices require state of the art processing equipment for the deposition of thin dielectric films and for controlled doping of the devices. Key techniques include the deposition of stoichiometric and silicon rich silicon nitride and silicon dioxide films, and the controlled wafer doping with boron and phosphorus. A state of the art furnace stack is to be procured which will satisfy these requirements on industrially relevant wafer sizes up to 150mm. The equipment will support a broad range of research projects in the above fields, ranging from fundamental investigations to applied research carried out in collaboration with industry partners.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
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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The LASE process - a new approach to cost effective thin solar cells. This project aims to develop a process to produce a new type of single
crystalline silicon solar cell. The cell is made on very thin slices of silicon that are detached from a conventional high quality silicon wafer. The wafer is gradually consumed as successive slices are harvested from it. Substantially less silicon is used in each solar cell, which allows significant cost reductions.
Low cost photovoltaic modules through reduced silicon consumption. Aims: The project aims to develop new methods and processes for the production of solar cells and photovoltaic modules. The modules will be made from very thin, narrow silicon solar cells. Because the modules use much less silicon than conventional modules, they are expected to be substantially cheaper.
Expected outcomes: It is expected that the project will lead to implementation of the proposed technology in a pilot plant and ....Low cost photovoltaic modules through reduced silicon consumption. Aims: The project aims to develop new methods and processes for the production of solar cells and photovoltaic modules. The modules will be made from very thin, narrow silicon solar cells. Because the modules use much less silicon than conventional modules, they are expected to be substantially cheaper.
Expected outcomes: It is expected that the project will lead to implementation of the proposed technology in a pilot plant and commercialisation thereafter.
Significance: Successful commercialisation will result in a significant reduction in the cost of photovoltaic modules as well as substantial economic benefits to the commercial partner and Australia.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
Lifetime spectroscopy of impurities in silicon solar cells. This project aims to apply recently developed experimental techniques to the important problem of characterising impurities in silicon, with a strong focus on solar cell applications. These new spectroscopic techniques, which are based on carrier lifetime measurements, are more sensitive and less ambiguous than most existing methods. The results will have important implications for solar cell technologies in two independent ways - first ....Lifetime spectroscopy of impurities in silicon solar cells. This project aims to apply recently developed experimental techniques to the important problem of characterising impurities in silicon, with a strong focus on solar cell applications. These new spectroscopic techniques, which are based on carrier lifetime measurements, are more sensitive and less ambiguous than most existing methods. The results will have important implications for solar cell technologies in two independent ways - firstly, by allowing accurate diagnosis of the performance-limiting impurities in standard silicon solar cells - and secondly, by identifying particular impurities which could boost cell performance beyond the conventional limit through the impurity photovoltaic effect.Read moreRead less