Abstract
A bifacial silicon solar cell under monochromatic illumination in frequency modulation by the rear side is being studied for the optimization of base thickness. The density of photogenerated carriers in the base is obtained by resolution of the continuity equation, with the help of boundary conditions at the junction surface (n+/p) and the rear face (p/p+) of the base. For a short wavelength corresponding to a high absorption coefficient, the AC photocurrent density is calculated and represented according to the excess minority carrier’s recombination velocity at the junction, for different modulation frequency values. The expression of the AC recombination velocity of excess minority carriers at the rear surface of the base of the solar cell is then deduced, depending on both, the absorption coefficient of the silicon material and the thickness of the base. Compared to the intrinsic AC recombination velocity, the optimal thickness is extracted and modeled in a mathematical relationship, as a decreasing function of the modulated frequency of back illumination. Thus under these operating conditions, a maximum short-circuit photocurrent is obtained and a low-cost bifacial solar cell can be achieved by reducing material (Si) to elaborate the base thickness.
Highlights
The photovoltaic effect is the result of photon-matter interaction in a semiconductor
A bifacial silicon solar cell under monochromatic illumination in frequency modulation by the rear side is being studied for the optimization of base thickness
The surface recombination velocity expressions depend on the frequency (ω) modulation [64] [65] that acts on the relaxation of excess minority carriers, and the monochromatic absorption coefficient [8] [12], which defines the depth of light penetration, are considered for the base optimum thickness (H) determination
Summary
The photovoltaic effect is the result of photon-matter interaction in a semiconductor. The proposed study involves a bifacial solar cell with crystalline silicon (n+/p/p+), illuminated by the rear side (p+) with a monochromatic light (λ) in frequency modulation (ω) in order to determine the thickness of its base, allowing to produce the maximum short circuit photocurrent. The surface recombination velocity expressions depend on the frequency (ω) modulation [64] [65] that acts on the relaxation of excess minority carriers, and the monochromatic absorption coefficient [8] [12], which defines the depth of light penetration, are considered for the base optimum thickness (H) determination
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