We have developed a three-dimensional numerical model of grain boundaries to simulate the electrical properties of polycrystalline silicon with doping densities larger than approximately We show that three-dimensional effects play an important role in quantifying the minority-carrier properties of polycrystalline silicon. Our simulations reproduce the open-circuit voltage of a wide range of published experiments on thin-film silicon p-n junction solar cells, choosing a velocity parameter for recombination at the grain boundaries, S, in the order of The simulations indicate that, although S has been reduced by one order of magnitude over the last two decades, improvements in the open-circuit voltage have mainly been achieved by increasing the grain size. A few options are proposed to further reduce S.
REFERENCES
1.
S.
Edmiston
, G.
Heiser
, A. B.
Sproul
, and M. A.
Green
, J. Appl. Phys.
80
, 6783
(1996
).2.
3.
4.
5.
6.
7.
8.
9.
10.
S. J.
Robinson
, S. R.
Wenham
, P. P.
Altermatt
, A. G.
Aberle
, G.
Heiser
, and M. A.
Green
, J. Appl. Phys.
78
, 4740
(1995
).11.
Integrated Systems Engineering AG, Zurich, Switzerland, DESSIS manual version 6.1, 2000.
12.
P. P.
Altermatt
, G.
Heiser
, A. G.
Aberle
, A.
Wang
, J.
Zhao
, S. J.
Robinson
, S.
Bowden
, and M. A.
Green
, Prog. Photovoltaics
4
, 399
(1996
).13.
P. P. Altermatt, J. O. Schumacher, A. Cuevas, S. W. Glunz, R. R. King, G. Heiser, and A. Schenk, in Proceedings of the 16th EC Solar Energy Conference, (James & James, London, UK, 2000).
14.
15.
G.
Baccarani
, B.
Riccò
, and G.
Spadini
, J. Appl. Phys.
49
, 5565
(1978
).16.
N. C. C.
Lu
, L.
Gerzberg
, and J. D.
Meindl
, IEEE Electron Device Lett.
1
, 38
(1980
).17.
18.
19.
20.
I.
Yamamoto
and H.
Kuwano
, Jpn. J. Appl. Phys., Part 2
31
, L1381
(1992
).21.
A. K.
Ghosh
, C.
Fishman
, and T.
Feng
, J. Appl. Phys.
51
, 446
(1980
).22.
R. B. Bergmann and J. H. Werner, in Symposium Proceedings of the European Material Research Society, Strasbourg, France, May, 2001.
23.
J.
Oualid
, M.
Bonfils
, J. P.
Crest
, G.
Mathian
, H.
Amzil
, J.
Dugas
, M.
Zehaf
, and S.
Martinuzzi
, Rev. Phys. Appl.
17
, 119
(1982
).24.
J.
Oualid
, C.
Singal
, J.
Dugas
, J.
Crest
, and H.
Amzil
, J. Appl. Phys.
55
, 1195
(1984
).25.
26.
27.
P.
Panayotatos
, E. S.
Yang
, and W.
Hwang
, Solid-State Electron.
25
, 417
(1982
).28.
C.
Feldman
, N. A.
Blum
, H. K.
Charles
, and F. G.
Satkiewicz
, J. Electron. Mater.
7
, 309
(1978
).29.
C. Feldman, N. A. Blum, and F. G. Satkiewicz, Proceedings of the 14th IEEE Photovoltaic Specialists Conference (IEEE, New York, 1980), pp. 391–396.
30.
C.
Feldman
, F. G.
Satkiewicz
, and N. A.
Blum
, Thin Solid Films
90
, 461
(1982
).31.
T. L.
Chu
, H. C.
Mollenkopf
, and S. C.
Chu
, J. Electrochem. Soc.
123
, 106
(1976
).32.
T. L. Chu, S. S. Chu, E. D. Stokes, C. L. Lin, and R. Abderrassoul, Proceedings of the 13th IEEE Photovoltaic Specialists Conference (IEEE, New York, 1978), pp. 1106–1110.
33.
M. Deguchi, H. Morikawa, T. Itagaki, T. Ishihara, and H. Namizaki, Proceedings of the 22nd IEEE Photovoltaic Specialists Conference (IEEE, New York, 1991), pp. 986–991.
34.
A. Takami, S. Arimoto, H. Morikawa, S. Hamamoto, T. Ishihara, H. Kumabe, and T. Murotani, Proceedings of the 12th European Photovoltaic Solar Energy Conference (Stephens and Associates, Bedford, UK, 1994), pp. 59–62.
35.
A. M. Barnett, R. B. Hall, D. A. Fardig, and J. S. Culik, Proceedings of the 18th IEEE Photovoltaic Specialists Conference (IEEE, New York, 1985), pp. 1094–1099.
36.
J. A. Rand, J. E. Cotter, C. J. Thomas, A. E. Ingram, Y. B. Bai, T. R. Ruffins, and A. M. Barnett, Proceedings of the First World Conference on Photovoltaic (IEEE, New York, 1994), pp. 1262–1265.
37.
Y. Bai, D. H. Ford, J. A. Rand, R. B. Hall, and A. M. Barnett, Proceedings of the 26th IEEE Photovoltaic Specialists Conference (IEEE, New York, 1997), pp. 35–38.
38.
R. Auer, J. Zettner, J. Krinke, G. Polisski, T. Hierl, R. Hezel, M. Schulz, H. P. Strunk, F. Koch, D. Nikl, and H. Campe, Proceedings of the 26th IEEE Photovoltaic Specialists Conference (IEEE, New York, 1997), pp. 739–742.
39.
T. Mishima, S. Itoh, G. Matuda, M. Yamamoto, K. Yamamoto, H. Kiyama, and T. Yokoyama, Technical Digest of the 9th International Photovoltaic Science and Engineering Conference (1996), pp. 243–244.
40.
A. K. Ghosh, T. Feng, and H. P. Maruska, Proceedings of the 14th IEEE Photovoltaic Specialists Conference (IEEE, New York, 1980), pp. 1169–1172.
41.
C. Hebling, S. W. Glunz, J. O. Schumacher, and J. Knobloch, Proceedings of the 14th European Photovoltaic Solar Energy Conference (Stephens and Associates, Bedford, UK, 1997), pp. 2318–2323.
42.
K. R. Sarma, R. W. Gurtler, R. N. Legge, R. J. Ellis, and I. A. Lesk, Proceedings of the 15th IEEE Photovoltaic Specialists Conference (IEEE, New York, 1981), pp. 941–948.
43.
F. Tamura, Y. Okayasu, and K. Kumagai, Solar Energy Materials and Solar Cells, 34, 263 (1994).
44.
N.
Tsuya
, K. I.
Arai
, T.
Takeuchi
, T.
Ojima
, and A.
Kuroiwa
, Jpn. J. Appl. Phys., Part 1
19
, 13
(1979
).45.
K. Peter, R. Kopecek, J. Hötzel, P. Fath, E. Bucher, C. Zahedi, and F. Ferrazza, Technical Digest of the 12th International Photovoltaic Science and Engineering Conference (2001), pp. 77–78.
46.
G. Beaucarne, J. Poortmans, M. Caymax, J. Nijs, S. Bourdais, D. Angermeier, R. Monna, and A. Slaoui, Proceedings of the Second World Conference on Photovoltaic Solar Energy Conversion (James & James, London, UK, 1998), pp. 1814–1817.
47.
G. Beaucarne, M. Caymax, I. Peytier, and J. Poortmans, Solid State Phenomena (to be published).
48.
49.
C. H.
Seager
, P. M.
Lenahan
, K. L.
Brower
, and R. E.
Mikawa
, J. Appl. Phys.
58
, 2704
(1985
).50.
51.
A.
Gómez
, L.
Beltrán
, J. L.
Aragón
, and D.
Romeu
, Scr. Mater.
38
, 795
(1998
).52.
53.
54.
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