Effective Lifetime Experimental Measurement under External Magnetic Field in Transient Dynamic State Obtained from a Square Electrical Excitation by Open Circuit Voltage Decay Method
In this work, we present an experimental transient 3-Dimensionnal study for the minority charge carriers’ effective lifetime measurement under magnetic field in transient dynamic state. The magnitude of the magnetic field B is varied from 0 mT to 0.03 mT. The method used is mainly based on the open circuit voltage decay method. The solar cell is injected by a low electrical excitation which protects against capacitance effects. Our approach is based on the open circuit voltage decay response analysis. From an experimental set-up, we get the transient voltage data on a digital scope. The data are used for plotting transient voltage decay curves. The curves obtained and analyzed are fitted in their linear zone. This zone presents an ideal decay which permits to get good values of lifetime. The slope of the linear decay is inversely proportional to effective lifetime. The results of fitting permit determinate the effective charge carriers’ lifetime directly. The results obtained are then presented and analyzed. The observations indicate that the charge carriers effective lifetime decrease when the magnetic field increases.
References
[1]
Dhariwhal, S.R. and Vasu, N.K. (1981) A Generalised Approach to Lifetime Measurement in p-n Junction Solar Cells. Solid-State Electronics, 24, 915-927. https://doi.org/10.1016/0038-1101(81)90112-X
[2]
Gossick, B.R. (1953) Post-Injection Barrier Electromotive Force of p - n Junctions. Physical Review Journals Archive, 91, 1012. https://doi.org/10.1103/PhysRev.91.1012
[3]
Lederhander, S.R. and Giacoletto, L.J. (1955) Measurement of Minority Carrier Lifetime and Surface Effects in Junction Devices. Proceedings of the IRE, Vol. 43, 477-483. https://doi.org/10.1109/JRPROC.1955.277857
[4]
Green, M.A. (1983) Minority Carrier Lifetime Using Compensated Differential Open Circuit Voltage Decay. Solid-State Electronics, 26, 1117-1122. https://doi.org/10.1016/0038-1101(83)90011-4
[5]
Ray, U.C., Agarwal, S.K. and Jain, S.C. (1982) Theory and Experiments on Open Circuit Voltage Decay of p-n Junction Diodes with Arbitrary Base Width, Including, the Effects of Built in Drift Field in the Base and Recombination in the Emitter. Journal of Physic, 53, 9112.
[6]
Sam, R., Zouma, B., Zougmoré, F., Koalaga, Z., Zoungrana, M. and Zerbo, I. (2012) 3D Determination of the Minority Carrier Lifetime and the p-n Junction Recombination Velocity of a Polycrystalline Silicon Solar Cell. IOP Conference Series: Materials Science and Engineering, Ouagadougou, 17-22 October 2011, Vol. 29. https://doi.org/10.1088/1757-899X/29/1/012018
[7]
Sam, R., Kaboré, K. and Zougmoré, F. (2016) A Three-Dimensional Transient Study of a Polycritsalline Silicon Solar Cell under Constant Magnetic Field. International Journal of Engineering Research, 5, 93-97.
[8]
Diasso, A., Sam, R. and Zougmoré, F. (2020) External Magnetic Field and Air Mass Effects on Carrier’s Effective Lifetime of a Bifacial Solar Cell under Transient State. Research Journal of Applied Sciences, Engineering and Technology, 4, 140-146. https://doi.org/10.19026/rjaset.17.6026
[9]
Muralidharan, R., Jain, S.C. and Jain, U. (1982) Determination of the Minority Carrier Lifetime in the Base of a Back-Surface Field Solar Cell by Forward Current-Induced Voltage Decay and Photovoltage Decay Methods. Solar Cells, 6, 162-176. https://doi.org/10.1016/0379-6787(82)90064-3
[10]
Diasso, A., Sam, R., Yacouba, N.T. and Zougmoré, F. (2020) Effects of External Magnetic Field and Air Mass on Space Charge Width Extension of a Bifacial Solar Cell Front Side Illumination. International Journal of Energy and Power Engineering, 9, 29-34. https://doi.org/10.11648/j.ijepe.20200903.11
