Asked by UNO
The figure below presents the EQE of a triple junction solar cell with junctions A, B and C under short circuited (V = 0 V) condition.
EQE table is:
A: EQE = 0.7 wavelength= 300 to 650 nm
B: EQE = 0.9 Wavelength= 650 to 850 nm
C: EQE = 0.8 Wavelength= 850 to 1250 nm
a) What is the bandgap (in eV) of the absorber layer of the junction A?
b) What is the bandgap (in eV) of the absorber layer of the junction B?
c) What is the bandgap (in eV) of the absorber layer of the junction C?
d) Which of the following statements is TRUE?
Junction C acts as the top cell, Junction B as the middle cell, and Junction A as the bottom cell.
Junction B acts as the top cell, Junction C as the middle cell, and Junction A as the bottom cell.
Junction A acts as the top cell, Junction B as the middle cell, and Junction C as the bottom cell
TRIPLE JUNCTION SOLAR CELL - III
Each junction is illuminated under standard test conditions. Given the photon fluxes below, calculate the short-circuit current density (in mA/cm2) of each (separate) junction (A, B and C):
ϕ=9.3∗1020m−2s−1 for 300nm<λ<650nm
ϕ=8.4∗1020m−2s−1 for 650nm<λ<850nm
ϕ=1.4∗1021m−2s−1 for 850nm<λ<1250nm
e) Jsc of Junction A:
f) Jsc of Junction B:
g) Jsc of Junction C:
TRIPLE JUNCTION SOLAR CELL - IV
h) The Voc of each junction in V can be roughly estimated by the equation
Voc=Egap(J)2q=Egap(eV)2
where q is the elementary charge, Egap(J) is the bandgap energy expressed in Joules, and Egap(eV) is the bandgap energy expressed in eV. Assume a fill factor of FF=0.75. What is then the efficiency (in %) of the triple junction solar cell?
EQE table is:
A: EQE = 0.7 wavelength= 300 to 650 nm
B: EQE = 0.9 Wavelength= 650 to 850 nm
C: EQE = 0.8 Wavelength= 850 to 1250 nm
a) What is the bandgap (in eV) of the absorber layer of the junction A?
b) What is the bandgap (in eV) of the absorber layer of the junction B?
c) What is the bandgap (in eV) of the absorber layer of the junction C?
d) Which of the following statements is TRUE?
Junction C acts as the top cell, Junction B as the middle cell, and Junction A as the bottom cell.
Junction B acts as the top cell, Junction C as the middle cell, and Junction A as the bottom cell.
Junction A acts as the top cell, Junction B as the middle cell, and Junction C as the bottom cell
TRIPLE JUNCTION SOLAR CELL - III
Each junction is illuminated under standard test conditions. Given the photon fluxes below, calculate the short-circuit current density (in mA/cm2) of each (separate) junction (A, B and C):
ϕ=9.3∗1020m−2s−1 for 300nm<λ<650nm
ϕ=8.4∗1020m−2s−1 for 650nm<λ<850nm
ϕ=1.4∗1021m−2s−1 for 850nm<λ<1250nm
e) Jsc of Junction A:
f) Jsc of Junction B:
g) Jsc of Junction C:
TRIPLE JUNCTION SOLAR CELL - IV
h) The Voc of each junction in V can be roughly estimated by the equation
Voc=Egap(J)2q=Egap(eV)2
where q is the elementary charge, Egap(J) is the bandgap energy expressed in Joules, and Egap(eV) is the bandgap energy expressed in eV. Assume a fill factor of FF=0.75. What is then the efficiency (in %) of the triple junction solar cell?
Answers
Answered by
cole
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Answered by
Indian guy
I send you something for sure. wait And see.
Answered by
mansour Thabet
Voc=Egap(J)2q=Egap(eV)2
where q is the elementary charge, Egap(J) is the bandgap energy expressed in Joules, and Egap(eV) is the bandgap energy expressed in eV. Assume a fill factor of FF=0.75. What is then the efficiency (in %) of the triple junction solar cell?
where q is the elementary charge, Egap(J) is the bandgap energy expressed in Joules, and Egap(eV) is the bandgap energy expressed in eV. Assume a fill factor of FF=0.75. What is then the efficiency (in %) of the triple junction solar cell?
Answered by
NOUREDINE
What is the meaning solar cell absorbs photons
Answered by
NOUREDINE
shows the mass of the solar spectrum streamlined air AM1.5 radiation at 1000 watts per square meter. Spectrum is divided into three spectral areas:
A for wavelengths [0nm <λ <620nm]
B for wavelengths [620nm <λ <1240nm]
C for wavelengths [1240nm <λ <1860nm]
A for wavelengths [0nm <λ <620nm]
B for wavelengths [620nm <λ <1240nm]
C for wavelengths [1240nm <λ <1860nm]
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