Abstract
The technological development of silicon wafer processing for solar cells by multiwire sawing is mainly driven by the need to reduce cost but under the condition to maintain or even improve the wafer quality. This additional requirement becomes even more important because wafer and wire thickness will decrease in the future and the standard loose abrasive sawing technique will be replaced by the fixed abrasive sawing technique.
The essential quality parameters for wafers are total thickness variations (TTV), roughness and grooves, subsurface damage, and fracture strength stability. These factors depend on the properties of wires, consumables, and machine sawing parameters. Their investigation and determination require adequate characterization methods. The chapter describes standard and new methods, which have been developed to characterize wafers, wires, and consumables. Today’s optimization processes also require a basic understanding of the interaction processes between wires, sawing fluid, and the silicon material. Special experimental methods, which have been developed to investigate the fundamental micromechanical processes and their ramifications on the wafer quality parameters, are presented.
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References
O. Anspach, B. Hurka, K. Sunder, Solar Energy Materials and Solar Cells 131, 58 (2014)
G.R. Anstis, P. Chantikul, B.R. Lawn, D.B. Marshall, J. Am. Ceram. Soc. 64–9, 533 (1981)
A. Bidiville, K. Wasmer, R. Kraft, C. Ballif, Proceedings of 24th EU PVSEC (WIP, München, 2009), p. 1400
A. Bidiville, K. Wasmer, J. Michler, P.M. Nasch, M. Van der Meer, C. Ballif, Prog. Photovolt. Res. Appl. 18, 563 (2010)
J.I. Bye, L. Norheim, B. Holme, Ø. Nielsen, S. Steinsvik, S.A. Jensen, G. Fragiacomo, I. Lombardi, Proceedings of 26th EU PVSEC (WIP, München, 2011), p. 956
R. Chauhan, Y. Ahn, S. Chandrasekar, T. Farris, Wear 166, 246 (1993)
C.P. Chen, M. Leipold, J. Am. Ceram. Soc. 59, 342 (1980)
L.M. Cook, J. Non-Cryst. Solids 120, 152 (1990)
V. Domnich, Y. Gogotsi, Rev. Adv. Mater. Sci. 3, 1 (2002)
A.G. Evans, D.B. Marshall, Fund. of Friction and Wear (ASM, Metals Park, 1981), p. 441
C. Funke, E. Kullig, M. Kuna, H.J. Möller, Adv. Eng. Mater. 6, 594 (2004)
R. Gassilloud, C. Ballif, P. Gasser, G. Buerki, J. Michler, Phys. Status Solidi (a) 202(15), 2858 (2005)
H.D. Geiler, H. Karge, M. Wagner, St. Eichler, M. Jurisch, U. Kretzer, M. Scheffer-Czygan, Mater. Sci. Semicond. Process. 9, 345 (2006)
Y. Gogotsi, C. Baek, F. Kirscht, Semicond. Sci. Technol. 14, 936 (1999)
M. Hamblin, G. Stachowiak, Wear 190, 237 (1995)
A. Holt, A. Thøgersen, C. Rohr, J.-I. Bye, G. Helgesen, Ø. Nordseth, S.A. Jensen, L. Norheim, Ø. Nielsen, Proceedings of 25th EU PVSEC (WIP, München, 2010), p. 1617
ITRP, International Technology Roadmap for Photovoltaic, SEMI Europe Photovoltaics Group, (2016), http://itrpv.net
J. Jang, M.J. Lance, S. Wen, Acta Mater. 53, 1759 (2005)
B. Lawn, Fracture of Brittle Solids (Cambridge University Press, Cambridge, 1993)
H. Li, R. Bradt, J. Mater. Sci. 31, 1065 (1996)
T. Li, P. Ge, W. Bi, Y. Gao, Mat. Sci. in Semi. Processing 66, 53 (2016)
D. Meißner, St. Schönfelder, B. Hurka, J. Zeh, K. Sunder, R. Köpge, T. Wagner, A. Grün, H. Hagel, H.J. Möller, H. Schwabe, O. Anspach, Sol. Energy Mater. Sol. Cells 120, 346 (2014)
H. J. Möller, in Crystal Growth Technology, ed. by H. J. Scheel and P. Capper (Wiley - VCH Weinheim, 2008) p. 457
H. J. Möller, Handbook of Crystal Growth, vol. 2, 2nd edn.(Elsevier, 2014). Chapter 18
H. J. Möller, C. Funke, in Freiberger Forschungshefte B, ed. by H.J. Möller, G. Roewer (TU Bergakademie Freiberg, Freiberg, 2003), p. 230
H.J. Möller, S. Würzner, R. Buchwald, M. Herms, M. Wagner, Solid State Phenom. 242, 466 (2016)
T. Orellana Pérez, C. Schmid, S. Riepe, H.J. Möller, S. Reber, Proceedings of 24th European PVSEC (WIP, München, 2009), p. 1228
T. Orellana Pérez, E. M. Tejado, C. Funke, S. Riepe, J. Y. Pastor, H. J. Möller, J. Mat. Science (2014). https://doi.org/10.1007/s10853-014-8192-5
C. Poon, B. Bushan, Wear 190(76) (1995)
L.S. Ramsdell, Am. Mineral. 32, 64 (1945)
M. Verspui, G. de With, P. van der Varst, M. Buijs, Wear 188, 102 (1995)
T. Wagner, T. Behm, R. Rietzschel, S. Kaminski, C. Funke, H.J. Möller, Proceedings of 25th EU PVSEC (WIP, München, 2010), p. 1267
S. Würzner, R. Buchwald, S. Retsch, H.J. Möller, Proceedings of 29th EU PVSEC (WIP, München, 2014a), p. 742
S. Würzner, R. Buchwald, H.J. Möller, Phys. Status Solidi C 12–8, 1119 (2014b)
S. Würzner, A. Falke, R. Buchwald, H.J. Möller, Energy Procedia 77, 881 (2015)
S. Würzner, M. Herms, T. Kaden, H. J. Möller, M. Wagner, Energies 10, 414 (2017)
J. Yan, T. Asami, T. Kuriyagawa, Precis. Eng. 32, 186 (2008)
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Möller, H.J. (2018). Characterization of Wafers and Supply Materials. In: Yang, D. (eds) Handbook of Photovoltaic Silicon. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-52735-1_18-1
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DOI: https://doi.org/10.1007/978-3-662-52735-1_18-1
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