论文信息 - Towards high-efficiency thin-film silicon solar cells with the “micromorph” concept

Towards high-efficiency thin-film silicon solar cells with the “micromorph” concept

Tandem solar cells with a microcrystalline silicon bottom cell (1 eV gap) and an amorphous-silicon top cell (1.7 eV gap) have recently been introduced by the authors; they were designated as “micromorph” tandem cells. As of now, stabilised efficiencies of 11.2% have been achieved for micromorph tandem cells, whereas a 10.7% cell is confirmed by ISE Freiburg. Micromorph cells show a rather low relative temperature coefficient of 0.27%/K. Applying the grain-boundary trapping model so far developed for CVD polysilicon to hydrogenated microcrystalline silicon deposited by VHF plasma, an upper limit for the average defect density of around 2 × 1016/cm3 could be deduced; this fact suggests a rather effective hydrogen passivation of the grain-boundaries. First TEM investigations on μc-Si : H p-i-n cells support earlier findings of a pronounced columnar grain structure. Using Ar dilution, deposition rates of up to 9 A/s for microcrystalline silicon could be achieved.

[1] N. Wyrsch,et al. High-rate deposition of amorphous hydrogenated silicon: effect of plasma excitation frequency , 1987 .

[2] Herbert Keppner,et al. Device grade microcrystalline silicon owing to reduced oxygen contamination , 1996 .

[3] Arvind Shah,et al. Complete microcrystalline p-i-n solar cell—Crystalline or amorphous cell behavior? , 1994 .

[4] Reinhard Carius,et al. Improvement of grain size and deposition rate of microcrystalline silicon by use of very high frequency glow discharge , 1994 .

[5] J. Meier,et al. Electrical properties and degradation kinetics of compensated hydrogenated microcrystalline silicon deposited by very high‐frequency‐glow discharge , 1995 .

[6] R. Evershed,et al. Mat Res Soc Symp Proc , 1995 .

[7] J. Seto. The electrical properties of polycrystalline silicon films , 1975 .