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Defect mapping in full-size multi-crystalline Si wafers

Published online by Cambridge University Press:  15 July 2004

S. Ostapenko  and
M. Romero
S. Ostapenko*
Affiliation:
University of South Florida, 4202 E Fowler Avenue, Tampa, Florida, 33620, USA
M. Romero
Affiliation:
National Renewable Energy Laboratory, Golden CO, USA
*
[email protected]
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Abstract

Application of scanning techniques is strongly required for in-line/off-line diagnostics of semiconductors with spatial inhomogeneity of electronic properties due to uneven defect distribution. The defect mapping allows performing an initial screening and follow-up local analyses in large-scale materials and devices for electronic applications. This approach is illustrated on multi-crystalline silicon (mc-Si) wafers for solar cells. Four different mapping techniques were applied concurrently to full-size as-grown and processed mc-Si. They include the mapping of (1) minority carrier lifetime, (2) room-temperature photoluminescence, (3) dislocation density, and (4) temperature dependent EBIC and cathodoluminescence. Analyses revealed a clear correlation between the “defect” PL band intensity with the maximum at about 0.8 eV and concentration of the dislocations contaminated by impurities and defects. The 0.8 eV band has a distinctive location at wafer areas with reduced minority carrier lifetime, i.e. regions with enhanced recombination activity of defects. It is demonstrated that the concentration of the 0.8 eV defects has analytical relation to the concentration of non-radiative defects in dislocated regions. The model of these defects is discussed.

Keywords

Type
Research Article
Information
The European Physical Journal - Applied Physics , Volume 27 , Issue 1-3: Tenth International Conference on Defects: Recognition, Imaging and Physics in Semiconductors (DRIP X) , July 2004 , pp. 55 - 58
Copyright
© EDP Sciences, 2004

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References

D. K. Schroder, Semiconductor material and device characterization, 2nd edn. (J. Wiley & Sons, 1998), pp. 420–508
V. Higgs, F. Chin, X. Wang, Solid State Phenom. 63/64, 421 (1998)
J. Bailey, J. P. Kalejs, C. Keaveny, in Proceedings of the 1st World Conf. on Photovoltaic Energy Conversion (New York, IEEE, 1995), p. 1356
Ostapenko, S., Tarasov, I., Kalejs, J. P., Haessler, C., Reisner, E.-U., Semicond. Sci. Technol. 15, 840 (2000) CrossRef
Kittler, M., Seifert, W., Arguirov, T., Tarasov, I., Ostapenko, S., Solar Energy Mater. and Solar Cells 72, 465 (2002) CrossRef
Y. Koshka, S. Ostapenko, J. Cho, J. P. Kalejs, in Proceedings of 26th IEEE Photovoltaic Specialists Conference (Anaheim, CA, 1997), p. 115
Tajima, M., Tokita, M., M.Warashina, Mater. Sci. Forum 196-201, 1749 (1995) CrossRef