American Journal of Physics and Applications
Volume 5, Issue 6, November 2017, Pages: 106-108
Received: Jun. 22, 2017;
Accepted: Jul. 5, 2017;
Published: Nov. 8, 2017
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Krutikov Vladimir Nikolaevich, All-Russian Research Institute for Optophysical Measurements (VNIIOFI), Moscow, Russia
Parfentiev Nikolay Andreevich, All-Russian Research Institute for Optophysical Measurements (VNIIOFI), Moscow, Russia
A new method for calculation the spectral sensitivity of solar cells based on data obtained by measurement of differential sensitivity. As follows from the conducted analysis, measurements of cells can be carried out only at a constant spectral composition of background radiation. In particular with a single powerful lamp is repositionable relative to the cell. In the practical application of the method is expected to increase the accuracy of determining the spectral sensitivity, especially in the region of large wavelengths, where there is the maximum nonlinearity of the dependence of a current on irradiance.
Krutikov Vladimir Nikolaevich,
Parfentiev Nikolay Andreevich,
The Method of Calculating the Spectral Sensitivity of Solar Cells, American Journal of Physics and Applications.
Vol. 5, No. 6,
2017, pp. 106-108.
Copyright © 2017 Authors retain the copyright of this article.
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Metzdorf and all. Radiometry in voltaic: calibration of reference solar cells and evaluation of reference value. Metrologia, 2000, v. 37, p 573-578.
Fidanyan, G. S., Morozova S. P., Parfentiev N. A. Setup for measuring the absolute spectral sensitivity of the solar cell under standard conditions. XXIV International scientific-technical conference and school on Photonics and night vision devices. 22-27 May 2016, page 258-262. Moscow, Russia.
W. Keogh and Blakers, A. W., “Natural Sunlight Calibration of Silicon Solar Cells”, 17th European Photovoltaic Solar Energy Conference. Munich, Germany, 2001.
K. Emery, Myers, D., and Rummel, S., “SOLAR SIMULATION - PROBLEMS AND SOLUTIONS”, 20th IEEE PV Specialists Conference. p. 1087, 1988.
D. King and Hansen, B., “A Sensitivity Analysis of the Spectral Mismatch Correction Procedure Using Wavelength-Dependent Error Sources”, 22nd IEEE PV Specialists Conference. 1991.
J. Zhao, A., W., Dai, X., Green, M. A., and Wenham, S. R., “Improvements in Silicon Solar Cell Performance”, 22nd IEEE PV Specialists Conference. pp. 399-402, 1991. M. Wolf and Rauschenbach, H., “Series Resistance Effects on Solar Cell Measurements”, Advanced Energy Conversion, vol. 3, 1963.
R. A. Sinton and Cuevas, A., “A Quasi-Steady-State Open-Circuit Voltage Method for Solar Cell Characterization”, in 16th European Photovoltaic Solar Energy Conference, Glasgow, Scotland, 2000, pp. 1152–1155.
M. J. Kerr, Cuevas, A., and Sinton, R. A., “Generalized analysis of quasi-steady-state and transient decay open circuit voltage measurements”, Journal of Applied Physics, vol. 91, p. 399, 2002.
A. Mette and et al, “Series resistance characterization of industrial silicon solar cells with screen-printed contacts using hotmelt paste”, Progress in Photovoltaics: Research and Applications, vol. 15, pp. 493-505, 2007.
D. PYSCH, Mette, A., and GLUNZ, S., “A review and comparison of different methods to determine the series resistance of solar cells”, Solar Energy Materials and Solar Cells, vol. 91, pp. 1698 - 1706, 2007.
S. Bowden and Rohatgi, A., “Rapid and Accurate Determination of Series Resistance and Fill Factor Losses in Industrial Silicon Solar Cells”, in 17th European Photovoltaic Solar Energy Conference, Munich, Germany, 2001.