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conversion at high light exposure in triple-junction designs with improved concentrator capabilities.
To meet the expected growth in demand for installed capacity, thin film CPV technology could prove to be a key enabler, provided that it can be developed in a robust fashion and costs can be reduced to be competitive. By focusing sunlight onto miniature high-efficiency tandem solar cells using high concentration lenses or mirrors, CPV systems are expected to reduce the cost of solar electricity by a significant amount, making it more commercially attractive to a wider audience.
SAFC Hitech is focusing on the supply of high purity chemicals at reduced cost to improve the process dynamics. Higher quality leads to higher efficiencies while lower raw material prices and more effective usage reduce overheads providing a more attractive final product cost. In particular, metalorganic production is being scaled up provide for increased volumes in an economically favorable manner.
Si nanoparticles in oxide for Si based solar cells - SAFC Hitech, along with a consortium of partners which includes CEA, INES, Tyndall Institute, TU Delft and Uppsala University, is participating in Semiconductor Nanomaterial for Advanced Photovoltaic Solar cells (or SNAPSUN), a European-based project that is working to develop thin-film coatings for standard silicon cells that aims to improve absorption across third generation solar technology.
Aiming to propose a clear and progressive approach toward optimized PV demonstration, with the active support of nanoscience and associated modelling, the SNAPSUN project’s primary goal is to show a PV proof of concept, with potential for very high conversion efficiency.
Expected to report its findings in March 2011, SNAPSUN is focused on Si-based nanotechnology and nanoscience studies to create a breakthrough semiconductor nanomaterial material with a high potential to solve issue of charge transport, along with related processes that will allow the fabrication of high efficiency PV devices avoiding scarce expensive elements.
Embedding nanoparticles in host matrices to enhance performance will require significant
August/September 2010
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precursor development to solve compatibility issues. The approach to be employed to develop the novel technologies will be two-fold path with an exploratory process first used to define the target structure and a production compatible process employed to develop a commercial technology. SAFC Hitech will be involved in the development of the latter process for industrial scale-up and implementation with specific attention to chemical solution provision for stable cocktails capable of direct use to form the nanoparticle in matrix films by simple coating mechanisms.
CdTe/CIGS sources for thin film devices - To support the existing CdTe and CIGS device manufacture on a large scale, SAFC Hitech can provide chemicals for both vapor phase and chemical deposition techniques. Optimization of complete vapor deposition technologies (TCO, Absorber and window layers) are being studied for an ongoing collaboration with teams involved in the PV21 SuperGEN project - the main UK government and industry supported University network currently in place.
This project is studying the commercial aspects of all the main existing technologies along with the viability of new disruptive approaches. In particular, new materials and surface structuring to improve performance have been targeted. The potential to eliminate toxic, high price, scarce elements from solar cell structures is highly attractive provided no decline in final product efficiency is observed and more importantly the price per watt of generated power remains competitive.
SAFC Hitech’s overall objectives are to support the development of technologies capable of improving solar cell products across the gamut of production processes currently proposed for high efficiency, low cost solar cell manufacture in the future and to ensure chemical products are available in the correct specification, volume and price to enable deployment of sufficient device areas to meet demand.
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