International Journal of Renewable Energy Research-IJRER

This paper presents the qualitative analysis of the variation of effective lifetime of minority carriers in p-type Si solar cell due to different recombination mechanisms associated with it. There is a direct relation between the minority carrier lifetime and the solar cell efficiency. The higher lifetime of minority carrier results in increased conversion efficiency of silicon solar cell. As silicon wafers are endowed with different crystal defects and grain boundaries, a reduced minority carrier lifetime is observed for both bulk and surface recombination processes that occur through these defects. A detailed knowledge of the role of recombination processes on carrier lifetime will facilitate the design of high efficiency solar cell.

A. Cuevas, D. Macdonald, Measuring and interpreting lifetime of silicon wafers, Solar Energy 76 (2004) 255-262.

R.A. Sinton and A. Cuevas, A quasi-steady-state open- circuit voltage method for solar cell characterisation, 16th European Photovoltaic Solar Energy Conference, 1-5 May, Glasgow, UK, 1152-1155 (2000).

S. Rein, Lifetime spectroscopy: A method of defect characterization in silicon for photovoltaic applications, Springer 2004, Berlin, Germany.

A. Hangleter, R. Hacker, Enhancement of band-to-band Auger recombination by electron-hole concentration, Phys. Rev. Lett. 65 (2), 215-18, (1990).

J. Dziewior, W. Schimd, Auger coefficients for highly doped and highly excited silicon, Appl. Phys. Lett. 31 (5) 346-8, (1997).

S.M. Sze, Physics of Semiconductor Devices, John Wiley & Sons, New York, 1981.

V. Grivickas, D. Noreika, J.A. Tellefsen, Surface and Auger recombination in silicon wafers of high carrier density, Lithunian Physics Journal 29 (5), 48-53, (1989).

R. Hall, Electron-hole recombination in germanium, Physics Review 87 (1952) 387.

W. Shockley, W. Read, Statistics of the recombinations of holes and electrons, Physical Rev.87 (1952) 835-842.