Nanostructured thin films for multiband-gap silicon triple junction solar cells

Publication date

2008

Authors

Schropp, R.E.I.ISNI 000000008094399X
Li, H. B. T.ISNI 0000000524044988
Franken, R.H.
Rath, J. K.ISNI 0000000350358433
van der Werf, C.H.M.
Schuttauf, J.A.ISNI 000000039514974X
Stolk, R P

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Abstract

By implementing nanostructure in multiband-gap proto-Si/proto-SiGe/nc-Si:H triple junction n–i–p solar cells, a considerable improvement in performance has been achieved. The unalloyed active layers in the top and bottom cell of these triple junction cells are deposited by Hot-Wire CVD. A significant current enhancement is obtained by using textured Ag/ZnO back contacts instead of plain stainless steel. We studied the correlation between the integrated current density in the long-wavelength range (650–1000 nm) with the back reflector surface roughness and clarified that the rms roughness from 2D AFM images correlates well with the long-wavelength response of the cell when weighted with a Power Spectral Density function. For single junction 2-μm thick nc-Si:H n–i–p cells we improved the Jsc from 15.2 mA/cm2 for plain stainless steel to 23.4 mA/cm2 using rough back reflector. We introduced profiling of the H2 dilution during growth of the nc-Si:H layer to prevent a transition to amorphous growth. The efficiency for a single junction n–i–p cell reached 8.5%, the highest reported value for HWCVD cells of this kind. Moreover, these cells show to be totally stable under light-soaking tests. Combining the above techniques, an efficiency of 10.9% has been obtained for triple junction cells (Jsc=8.35 mA/cm2, Voc=1.98 V, FF=0.661). By using effective light trapping techniques and three different band-gap materials, the required thickness could be kept small (∼2.5 μm total).

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Schropp, R E I, Li, H B T, Franken, R H, Rath, J K, van der Werf, C H M, Schuttauf, J A & Stolk, R L 2008, 'Nanostructured thin films for multiband-gap silicon triple junction solar cells', Thin Solid Films, vol. 516, no. 20, pp. 6818-6823.