Enhancing the performance of thin-film photovoltaic cells via the application of luminescent down-shifting layers. Photovoltaic (PV) devices convert sunlight directly into electricity. For decades, the dominant PV technology has been based on thick, costly silicon wafers. However, due to higher energy conversion efficiencies and manufacturing processes, thin film PV cells can provide lower price than of the conventional wafer-based technologies. This project takes one of the leading thin film ....Enhancing the performance of thin-film photovoltaic cells via the application of luminescent down-shifting layers. Photovoltaic (PV) devices convert sunlight directly into electricity. For decades, the dominant PV technology has been based on thick, costly silicon wafers. However, due to higher energy conversion efficiencies and manufacturing processes, thin film PV cells can provide lower price than of the conventional wafer-based technologies. This project takes one of the leading thin film technologies and couples it with a passive optical layer, which will result in a 30% performance enhancement by overcoming internal absorption losses. It is anticipated that the increased performance will enable the thin film PV technology to be far more commercially viable and attractive for future commercialisation, and hence reduce the cost of solar power.Read moreRead less
Unlocking the potential of n-type silicon for solar cells. This project will lead to an improved understanding of impurities in silicon, especially several emerging low-cost n-type silicon materials made especially for solar cells. This knowledge will enable the negative effects of these impurities to be eliminated or reduced, thus yielding higher efficiency modules that produce solar electricity at a lower cost. The potential benefits to Australia, which already has an established silicon solar ....Unlocking the potential of n-type silicon for solar cells. This project will lead to an improved understanding of impurities in silicon, especially several emerging low-cost n-type silicon materials made especially for solar cells. This knowledge will enable the negative effects of these impurities to be eliminated or reduced, thus yielding higher efficiency modules that produce solar electricity at a lower cost. The potential benefits to Australia, which already has an established silicon solar cell industry, are large. They include increased employment in well-paid high-technology jobs, increased export earnings, and reduced carbon dioxide emissions. These benefits could grow rapidly, in line with the global photovoltaic industry growth rate of more than 30% per year.Read moreRead less
Modifying Structure and Properties of Carbon Nanotubes for Device Applications (MWN). The focus of this project is to develop new heteroatom-doped carbon nanotube materials for use in conjugated-polymer composite photovoltaic cells. Synthesis of boron and of nitrogen doped carbon nanotubes (CNTs) by the US researchers will be complemented by ion-implantation post-synthesis of CNTs by the Australian team, to gain a thorough and detailed understanding of how the CNTs can act effectively as both an ....Modifying Structure and Properties of Carbon Nanotubes for Device Applications (MWN). The focus of this project is to develop new heteroatom-doped carbon nanotube materials for use in conjugated-polymer composite photovoltaic cells. Synthesis of boron and of nitrogen doped carbon nanotubes (CNTs) by the US researchers will be complemented by ion-implantation post-synthesis of CNTs by the Australian team, to gain a thorough and detailed understanding of how the CNTs can act effectively as both an electron acceptor and charge transport medium in a conjugated polymer. Outcomes will include fundamental advances in our understanding of charge transport in the composite devices and prototype organic photovoltaic devices of improved efficiency.Read moreRead less
ARC Centre for Solar Energy Systems. The National Centre of Excellence for Solar Energy Systems will be an international leader in research, commercialisation and education in the area of solar energy conversion. Research will be conducted into solar cell and solar thermal technologies, including thin crystalline and amorphous silicon solar cells that use far less silicon than conventional cells; systems that concentrate sunlight by 50-500 times; and very efficient solar cells for use in concent ....ARC Centre for Solar Energy Systems. The National Centre of Excellence for Solar Energy Systems will be an international leader in research, commercialisation and education in the area of solar energy conversion. Research will be conducted into solar cell and solar thermal technologies, including thin crystalline and amorphous silicon solar cells that use far less silicon than conventional cells; systems that concentrate sunlight by 50-500 times; and very efficient solar cells for use in concentrator systems. Expected outcomes include long-term research, commercial research, publications, education, community outreach and commercialisation of solar energy technologies to benefit Australia's economy and environment.Read moreRead less
NANOSCALE NETWORKS OF ORGANIC POLYMER/C60 FULLERENE BLENDS FOR HIGH EFFICIENCY SOLAR CELLS. Recent demonstrations of increased efficiencies in polymer-fullerene blend plastic films provide the prospect of low cost photovoltaic elements with the potential for widespread application. Further progress with these materials is strongly indicated. We will characterise these materials at the nanoscale to make further improvements in film morphology and employ our expertise in experimental investigation ....NANOSCALE NETWORKS OF ORGANIC POLYMER/C60 FULLERENE BLENDS FOR HIGH EFFICIENCY SOLAR CELLS. Recent demonstrations of increased efficiencies in polymer-fullerene blend plastic films provide the prospect of low cost photovoltaic elements with the potential for widespread application. Further progress with these materials is strongly indicated. We will characterise these materials at the nanoscale to make further improvements in film morphology and employ our expertise in experimental investigation of transport properties to gain a more complete understanding of the electronic and photonic processes underlying photovoltaic efficiency. Australia is ideally situated geographically and has a strong tradition of inventive engineering from which we can benefit and capitalise significantly on further improvements in the materials to be investigated.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989858
Funder
Australian Research Council
Funding Amount
$857,230.00
Summary
Fabrication Facilities of Atomic-Scale and Nanostructured Materials for the Development of Novel Devices, Sensors, and Biomedical Components. Australia's energy, mining, metallurgical, defence, biomedical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economy's strength. Future progress of these industries will be largely driven by advances in materials. The installation of the proposed facilities will add a new ....Fabrication Facilities of Atomic-Scale and Nanostructured Materials for the Development of Novel Devices, Sensors, and Biomedical Components. Australia's energy, mining, metallurgical, defence, biomedical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economy's strength. Future progress of these industries will be largely driven by advances in materials. The installation of the proposed facilities will add a new dimension to high-level research performance and significantly enhance the capability for the development of advanced materials and biomedical components in Australia. The continual development of advanced material and biomedical components will potentially provide a sustainable means for meeting the increasing global challenge for the industries.Read moreRead less
Carrier dynamics in III-V semiconductor quantum dots and nanostructures. Quantum dots and related nanostructures are one of the most attractive topics in the recently years. This project will investigate the role of carrier dynamics in these nanostructures by using state-of-the-art ultrafast spectroscopy techniques. The wealth of information obtained from this study will not only enhance our knowledge base but also allow us to design high performance QD lasers and detectors and to demonstrate in ....Carrier dynamics in III-V semiconductor quantum dots and nanostructures. Quantum dots and related nanostructures are one of the most attractive topics in the recently years. This project will investigate the role of carrier dynamics in these nanostructures by using state-of-the-art ultrafast spectroscopy techniques. The wealth of information obtained from this study will not only enhance our knowledge base but also allow us to design high performance QD lasers and detectors and to demonstrate innovative optoelectronic devices for optical communication systems as well as quantum information processing. It will ensure that Australia is at the cutting edge of nanotechnology and optoelectronics research.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