Post-deposition processing options for high-efficiency sputtered CdS/CdTe solar cells

CdCl2 activation near 400 °C is known to be critically important for obtaining high efficiency CdS/CdTe solar cells. However, this treatment step behaves differently on high-temperature-grown CdTe than on lower-temperature-grown CdTe layers such as those grown by sputtering. On sputtered films, the...

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Bibliographic Details
Published in:Journal of applied physics 2014-02, Vol.115 (6)
Main Authors: Paudel, Naba R., Young, Matthew, Roland, Paul J., Ellingson, Randy J., Yan, Yanfa, Compaan, Alvin D.
Format: Article
Language:English
Subjects:
Accelerated life tests
Accelerated tests
Activation energy
Cadmium chloride
Cadmium sulfide
Cadmium tellurides
Deposition
Efficiency
Photovoltaic cells
Soda-lime glass
Solar cells
Sputtered films
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Summary:CdCl2 activation near 400 °C is known to be critically important for obtaining high efficiency CdS/CdTe solar cells. However, this treatment step behaves differently on high-temperature-grown CdTe than on lower-temperature-grown CdTe layers such as those grown by sputtering. On sputtered films, the post-deposition activation produces grain-boundary passivation, sulfur diffusion into CdTe, and substantial grain growth. Nevertheless, we find the CdCl2 process for sputtered films to be characterized by a single activation energy that we interpret as applying to S diffusion into CdTe. We find this activation energy to hold for CdCl2 treatments from 370 to 440 °C. The completed CdS/CdTe solar-cell structures showed somewhat poorer initial performance with activation above 420 °C, but, in this case, the cell efficiency increased after accelerated life testing at 85 °C, open-circuit biasing and one-sun illumination. With an optimized CdCl2 activation process, the use of oxygenated sputtered CdS, and low-iron soda-lime glass, cell efficiencies of 14.5% were achieved.
ISSN:0021-8979
1089-7550
DOI:10.1063/1.4864415