Manufacturing 100-µm-thick silicon solar cells with efficiencies greater than 20% in a pilot production line
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Reducing wafer thickness while increasing power conversion efficiency is the most effective way to reduce cost per Watt of a silicon photovoltaic module. Within the European project 20 percent efficiency on less than 100-µm-thick, industrially feasible crystalline silicon solar cells (“20plµs”), we study the whole process chain for thin wafers, from wafering to module integration and life-cycle analysis. We investigate three different solar cell fabrication routes, categorized according to the temperature of the junction formation process and the wafer doping type: p-type silicon high temperature, n-type silicon high temperature and n-type silicon low temperature. For each route, an efficiency of 19.5% or greater is achieved on wafers less than 100 µm thick, with a maximum efficiency of 21.1% on an 80-µm-thick wafer. The n-type high temperature route is then transferred to a pilot production line, and a median solar cell efficiency of 20.0% is demonstrated on 100-µm-thick wafers.
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TERHEIDEN, Barbara, Tabitha BALLMANN, Renate HORBELT, Yvonne SCHIELE, Sabine SEREN, Jan EBSER, Giso HAHN, 2015. Manufacturing 100-µm-thick silicon solar cells with efficiencies greater than 20% in a pilot production line. In: Physica Status Solidi (A) : Applications and Materials Science. 2015, 212(1), pp. 13-24. ISSN 0031-8965. eISSN 1521-396X. Available under: doi: 10.1002/pssa.201431241BibTex
@article{Terheiden2015Manuf-30916, year={2015}, doi={10.1002/pssa.201431241}, title={Manufacturing 100-µm-thick silicon solar cells with efficiencies greater than 20% in a pilot production line}, number={1}, volume={212}, issn={0031-8965}, journal={Physica Status Solidi (A) : Applications and Materials Science}, pages={13--24}, author={Terheiden, Barbara and Ballmann, Tabitha and Horbelt, Renate and Schiele, Yvonne and Seren, Sabine and Ebser, Jan and Hahn, Giso} }
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