Modeling improvement of spectral response of solar cells by deployment of spectral converters containing semiconductor nanocrystals
van Sark W.G.J.H.M.1, Meijerink A.2, Schropp R.E.I.2, van Roosmalen J.A.M.3, Lysen E.H.4
1Copernicus Institute, Utrecht University, CH Utrecht, the Netherlands
2Debye Institute, Utrecht University, CC Utrecht, the Netherlands
3ECN Solar Energy, ZG Petten, the Netherlands
4Utrecht Centre for Energy Research (UCE), Utrecht University, CH Utrecht, the Netherlands
Поступила в редакцию: 16 февраля 2004 г.
Выставление онлайн: 20 июля 2004 г.
A planar converter containing quantum dots as wavelength-shifting moieties on top of a solar cell were studied. The highly efficient quantum dots are to shift the wavelengths where the spectral response of the solar cell is low to wavelengths where the spectral response is high, in order to improve the conversion efficiency of the solar cell. It was calculated that quantum dots with an emission at 603 nm increase the multi-crystalline solar cell short-circuit current by nearly 10%. Simulation results for planar converters on hydrogenated amorphous silicon solar cells show no beneficial effects, due to the high spectral response at low wavelength.
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