The aim of this study is to show the influence of the wavelength on the electrical parameters of vertical parallel junction silicon solar cell by use of impedance spectroscopy technique. The Bode diagrams of the diffusion capacitance are shown for different wavelengths while the solar cell operates under both open circuit and short circuit conditions. The Nyquist diagram of the diffusion capacitance has shown the extension of the space charge region for various wavelengths.
The space charge region of a solar cell can be considered as a plane capacitor named transition capacitance [
We present on
Given that the contribution of the base to the photocurrent is larger than that of the emitter [
Taking into account the generation, recombination and diffusion phenomena in the base, the equation governing the variation of the minority carriers density δ(x, t) under modulation frequency [
D(ω) and τ are respectively, the excess minority carrier diffusion constant and lifetime.
The excess minority carriers’ density can be written as:
Carrier generation rate G(z, t) is given by:
Where
x is the base depth along x axis, ω is the angular frequency, z the base depth according to the vertical axis; and λ the wavelength.
If we replace Equation (2) into Equation (1), the temporary part is eliminated and we obtain:
The solution of this equation is:
Coefficients A and B are determined through the following boundary conditions [
- at the junction (x = 0):
Sf is the excess minority carriers recombination velocity at the junction.
- at the middle of the base (x = H/2):
The excess minority carriers in the base will flow to the two junctions by diffusion; the photocurrent density is given by the following expression:
where q is the elementary charge.
From the excess minority carriers’ density, we can deduce the photovoltage across the junction, according to the Boltzmann’s relation as follow:
with VT the thermal voltage, Nb the base doping density, ni the intrinsic carriers’ density.
The charge variation in the base leads to a corresponding photovoltage variation across the junction; this gives rise to an associated capacitance. This capacitance is mainly due to the fixed ionized charge (dark capacitance) at the junction boundaries and the diffusion process (diffusion capacitance) [
Given the photovoltage expression (eq.10), the capacitance can be rewritten as:
We present in this section the Nyquist and Bode diagrams [
The profiles of the module and its phase of capacitance versus the logarithm of the frequency for different wavelengths (short and long wavelength), are shown in Figures 2(a)-(c).
In
Beyond this cut-off frequency, the capacitance of the solar cell and its phase decreases very rapidly with the angular frequency. In fact, when the frequency is inside the cut-off, the solar cell operates in quasi-static regime and remains insensitive to frequency. For frequencies above the cut-off frequency, the stress of the material
becomes important to the point that photo generated minority carriers are poorly stored in the vicinity of the junction: this leads to a very low capacitance.
In
In
In terms of ac electrical analogy, our study reveals that the behavior of the capacitance- frequency is similar to that observed in the electronic filter low-pass type.
The Nyquist diagram is the representation of the imaginary part as a function of the real part of a complex quantity [
The imaginary part versus real part of the capacitance, for different wavelengths λ, is shown in
In
In the wavelength interval [0.44 μm; 0.50 μm], the diameter of the semicircles increases because the number of minority carriers stored in the vicinity of the junction also increases. It is noted that in the wavelength interval [0.58 μm; 0.7 μm], the diameter of the semicircles decreases in this case.
When the angular frequency tends to zero, the imaginary part of the capacitance is zero while its real part is equal to its open circuit value in quasi-static regime: it will have one large storage of minority carriers in the
vicinity of the junction. By cons, when the angular frequency approaches infinity, the imaginary and real parts are almost zero: there is no more storage therefore photo generated minority carriers at the junction. By this, we match the capacitance of the solar cell to the diameter of a semicircle obtained for a given depth z between the two angular frequency range (zero to infinity). When the depth z increases, the curves are semicircles at decreasing diameters since there’s a decrease in the number of minority carriers photo generated in the base of the solar cell and stored in the vicinity of the junction
The imaginary part versus real part of the capacitance t for different wavelengths, is shown in
In
i) the range of angular frequency [0; ωc], corresponds to a quart circle;
ii) the imaginary part as a function of the real part is a straight line in the interval [ωc; ¥].
When the depth z increases, the curves that shrink because the amplitudes of the imaginary and real parts of the capacitance decreases: this can be explained by a weak generation of minority carriers in a non relaxed solar cell under high frequency excitation.
In this paper, we have developed a mathematical/physical model which enables us to simulate the behavior of the vertical parallel junction solar cell from the frequency-dependence of the capacitance. The capacitance of the space charge region was studied using Bode and Nyquist diagrams while the solar cell remained either under open circuit or short circuit condition and illuminated with different wavelengths. For given operating point, the absorption coefficient influences the region where the carriers are photogenerated and then leads to different diameter of the C-ω curves. Indeed, for a given wavelength the diameter obtained under short circuit is larger than that calculated for the solar cell under open circuit condition, according to the extended space charge region theory.
GokhanSahin,MoustaphaDieng,Mohamed Abderrahim Ould ElMoujtaba,Moussa IbraNgom,AmaryThiam,GrégoireSissoko, (2015) Capacitance of Vertical Parallel Junction Silicon Solar Cell under Monochromatic Modulated Illumination. Journal of Applied Mathematics and Physics,03,1536-1543. doi: 10.4236/jamp.2015.311178