(43.82 %, or 44.05 %)-Limiting Highest Efficiencies, Obtained Respectively in
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Published:2023-11-01
Issue:6
Volume:1
Page:229-245
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ISSN:2786-7447
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Container-title:European Journal of Theoretical and Applied Sciences
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language:
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Short-container-title:ejtas
Reference17 articles.
1. Green, M.A., Dunlop, E.D., Levi, D.H., Hohl-Ebinger, J., Yoshita, M., Kopidakis, N., … & Hao, X. (2022). Solar cell efficiency tables (version 60). Progress in Photovoltaics Research & Applied, 30, 687-701. https://doi.org/10.1002/pip.3595 2. Green, M.A. (1981) Solar Cell Fill Factors: General Graph and Empirical Expressions. Solid-State Electronics, 24, 788-789. http://dx.doi.org/10.1016/0038-1101(81)90062-9 3. He, X., Li, C., Wu, L., Hao, X., Zhang, J., Feng, L., Tang, P., & Du, Z. (2022). First-principles investigation on the electronic structures of CdSe x S1-x and simulation of CdTe solar cell with a CdSe x S1-x window layer by SCAPS. RSC advances, 12(34), 22188–22196. https://doi.org/10.1039/d2ra03053e 4. Kate, O.M.T., Jong, M.D., Hintzen, H.T. & van der Kolk, E. (2013). Efficiency enhancement calculations of states-of-the-art solar cells by luminescent layers with spectral shifting, quantum cutting, and quantum tripling function. Journal of Applied Physics, 114, 084502, 1-9. http://doi.org/10.1063/1.4819237 5. Kittel, C. (1976). Introduction to Solid State Physics. New York: Wiley.
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