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Microcrystalline Silicon for Solar Cells at High Deposition Rates by Hot Wire Cvd

Published online by Cambridge University Press:  01 February 2011

R. E. I. Schropp
Affiliation:
Utrecht University, Debye Institute, Physics of Devices, 3508 TA Utrecht, The Netherlands
Y. Xu
Affiliation:
National Renewable Energy Laboratory, 1617 Cole Blvd., Golden, CO 80401, USA
E. Iwaniczko
Affiliation:
National Renewable Energy Laboratory, 1617 Cole Blvd., Golden, CO 80401, USA
G. A. Zaharias
Affiliation:
Chem. Engineering Dept., Stanford University, Stanford, CA 94305, USA
A. H. Mahan
Affiliation:
National Renewable Energy Laboratory, 1617 Cole Blvd., Golden, CO 80401, USA
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Abstract

We have explored which deposition parameters in Hot Wire CVD have the largest impact on the quality of microcrystalline silicon (μc-Si) made at deposition rates (Rd) < 10 Å/s for use in thin film solar cells. Among all parameters, the filament temperature (Tfil) appears to be crucial for making device quality films. Using two filaments and a filament-substrate spacing of 3.2 cm, μc-Si films, using seed layers, can be deposited at high Tfil (∼2000°C) with a crystalline volume fraction < 70-80 % at Rd's < 30 Å/s. Although the photoresponse of these layers is high (< 100), they appear not to be suitable for incorporation into solar cells, due to their porous nature. n-i-p cells fabricated on stainless steel with these i-layers suffer from large resistive effects or barriers, most likely due to the oxidation of interconnected pores in the silicon layer. The porosity is evident from FTIR measurements showing a large oxygen concentration at ∼1050 cm-1, and is correlated with the 2100 cm-1 signature of most of the Si-H stretching bonds. Using a Tfil of 1750°C, however, the films are more compact, as seen from the absence of the 2100 cm-1 SiH mode and the disappearance of the FTIR Si-O signal, while the high crystalline volume fraction (< 70-80 %) is maintained. Using this Tfil and a substrate temperature of 400°C, we obtain an efficiency of 4.9 % for cells with a Ag/ZnO back reflector, with an i-layer thickness of only ∼0.7 μm. High values for the quantum efficiency extend to very long wavelengths, with values of 33 % at 800 nm and 15 % at 900 nm, which are unequalled by a-SiGe:H alloys. Further, by varying the substrate temperature to enable deposition near the microcrystalline to amorphous transition (‘edge’) and incorporating variations in H2 dilution during deposition of the bulk, efficiencies of 6.0 % have been obtained. The Rd's of these i-layers are 8-10 Å/s, and are the highest to date obtained with HWCVD for microcrystalline layers used in cells with efficiencies of ∼6 %.

Type
Research Article
Copyright
Copyright © Materials Research Society 2002

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References

[1] Yamamoto, K., Yoshimi, M., Tawada, Y., Okamoto, Y., Nakajima, A., Igari, S., Appl. Phys. A 69 (1999) 179.Google Scholar
[2] Meier, J., Torres, P., Platz, R., Dubail, S., Kroll, U., Anna, J.A. Selvan, Pellaton Vaucher, N., Hof, Ch., Fischer, D., Keppner, H., Shah, A., Ufert, K.D., Giannoules, P., and Koehler, J., MRS Symp. Proc. 420, 3(1996).Google Scholar
[3] Klein, S., Finger, F., Carius, R., Kluth, O., Baia Neto, L., Wagner, H., Stutzmann, M., 17th European Photovoltaic Conference and Exhibition, München, 2226 October (2001), in press.Google Scholar
[4] Jones, S.J., Crucet, R., Deng, X., Williamson, D.L., and Izu, M., MRS Symp. Proc. 609, A4.5 (2000).Google Scholar
[5] Morrison, S., K, U.. Das, and Madan, A., NREL Report EL-520-31065, 179 (2001).Google Scholar
[6] Mahan, A.H., Xu, Y., Williamson, D.L., Beyer, W., Perkins, J.D., Vanecek, M., Gedvilas, L.M., and Nelson, B.P., J. Appl. Phys. 90, 5038(2001).Google Scholar
[7] Mahan, A.H., Xu, Y., Iwaniczko, E., Williamson, D.L., Nelson, B.P., and Wang, Q., J. non-Cryst. Sol., April (2002), in press.Google Scholar
[8] Nelson, B.P., Xu, Y., Mahan, A.H., Williamson, D.L., and Crandall, R.S., MRS Symp. Proc. 609, A22.8 (2000).Google Scholar
[9] Wang, Q., Iwaniczko, E., Xu, Y., Gao, W., Nelson, B.P., Mahan, A.H., Crandall, R.S., and Branz, H.M., MRS Symp. Proc. 609, A4.3 (2000).Google Scholar
[10] Zaharias, G. et al., these proceedingsGoogle Scholar
[11] See Fig. 1 in Mahan, A.H., Williamson, D.L., and Furtak, T.E., MRS Symp. Proc. 467, 657(1997).Google Scholar
[12] Schropp, R.E.I., Alkemade, P.F.A., and Rath, J.K., Solar Energy Materials & Solar Cells 65 (2000) 541.Google Scholar
13] Schropp, R.E.I. and Zeman, M., Amorphous and Microcrystalline Silicon Solar Cells: Modeling, Materials, and Device Technology, Kluwer Academic Publishers, ISBN 0-7923-8317-6 (Boston/Dordrecht/London, 1998).Google Scholar
[14] Rath, J.K., Meiling, H., and Schropp, R.E.I., Solar Energy Materials and Solar Cells 48 (1997) 269.Google Scholar
[15] See, for example, the proceedings of the 12th Int'l Photovoltaic Science and Engineering Conference, Jeju, Korea, 11-15 June (2001), and references therein.Google Scholar