Minority-carrier transport in nonuniformly doped silicon-an analytical approach

A general analytical solution for minority-carrier transport in a nonuniformly doped quasi-neutral silicon region is derived. It is shown that, in the cases of an exponential doping-density profile and a general power-law doping-density profile, a closed-form solution for the minority-carrier concen...

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Bibliographic Details
Published in:IEEE transactions on electron devices 1990-01, Vol.37 (1), p.210-221
Main Authors: Verhoef, L.A., Sinke, W.C.
Format: Article
Language:English
Subjects:
Closed-form solution
Doping profiles
Equations
Performance analysis
Photonic band gap
Photovoltaic cells
Quasi-doping
Radiative recombination
Semiconductor device doping
Silicon
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Summary:A general analytical solution for minority-carrier transport in a nonuniformly doped quasi-neutral silicon region is derived. It is shown that, in the cases of an exponential doping-density profile and a general power-law doping-density profile, a closed-form solution for the minority-carrier concentration can be obtained for doping densities up to 10/sup 20/ cm/sup -3/. In the analysis, the experimentally observed dependencies of minority-carrier lifetime, minority-carrier mobility, and bandgap narrowing on doping density are taken into account. Contrary to earlier analytical solutions, the solution is free of integrals of minority-carrier transport parameters over the semiconductor region under study. Three important bipolar device configurations in which a nonuniform doping density plays a role are analyzed with the analytical solution. The first is the drift-field solar cell, for which a factor-of-20 reduction in the dark saturation current compared with a uniformly doped solar cell is calculated. Second, the effective back-surface recombination velocity of a high/low junction back-surface field (BSF) cell is shown to decrease with increasing BSF region thickness. Third, the influence of surface recombination velocity on the minority-carrier concentration profile in a heavily doped emitter is reduced when a strong power law doping profile in an n-p junction device is used.< >
ISSN:0018-9383
1557-9646
DOI:10.1109/16.43818