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This is the starting point for doing the exercise: |
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| I |
= |
I1 · |
æ
ç
è |
exp |
eUeff
kT |
– 1 |
ö
÷
ø |
+ |
I2 · |
æ
ç
è |
exp |
eUeff
nkT |
– 1 |
ö
÷
ø |
+ |
Ueff
RSH |
– IPh |
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| |
| |
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| |
| |
| |
| |
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| Ueff |
= |
U – I
· RSE | |
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Discuss qualitatively the
influence of the two resistors (and, as a more minor point, the idealiy
factor n) on the IV characteristics. |
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We will get to this, but here we will actully discuss the questions
first quantitatively. As input parameters we need j1, j2
and the ideality factor n, which we take as (see also exercise 8.1-5) |
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- j1 = 10–9 A/cm2.
- j2 = 10–7 A/cm2.
- n = 2.
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All we have to do is to solve the the equation from above numerically for various
values of the parameters: - Series resistance RSE.
- Shunt resistance RSH.
- Diode ideality factor n.
- Pre-exponential factors I1 and I2.
- And possibly the whole thing as a function of temperature T.
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This is a big program, but it is not too difficult to see some major points. |
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Here is a plot of the IV characteristics of a typical solar cell with 5 different series resistances RSE. |
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Everything else has been kept "ideal". This means that the shunt resistance
RSH is very large ("infinity"), the ideality factor of the second diode is n
= 2, and the two pre-exponential factors are I1 = 0,1 µA and I2
= 10 µA. The photo current is 3 A. |
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Even without looking a the (numerically) calculated figure, we
can deduce qualitatively a few facts from our basic equation above, aw asked in the
exercise. |
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For I = 0 A, we have Ueff = U. That means that
all
IU-characteristics must run through UOC, no matter
what kind of serial resistance we might have. |
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For large negative U (reverse direction)
, the current I is simply constant. We loose a part of the applied voltage in the serial resistance, but that
does not effect the current. The characteristics in the 3rd quadrant thus does not depend on RSE
if |U| is large enough. |
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For large positive U (forward direction),
the diode by itself will admit large currents for voltages above about 0.5 V, i.e. the diode
resistance becomes very low. The IU-characteristics then must
be dominated by RSE; it will simply turn into an ohmic straight line
with a slope given by 1/RSE |
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In the fourth quadrant for voltages below UOC some of the voltage
drops a the series resistor. The magnitude of the current thus can only be lower than in the case without a series resistor. |
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All of this is exactly what the calculated figure shows- taking into account the
"Ohmic" straight line we could have derived most of the graph above without any quantitative calculations |
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We now can draw several conclusions: |
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1. The efficiency h is proportional to the product
of ISc · UOC · FF. As long as RSE
is not too large (e.g. RSE < 100 mW for the example given), series
resistances primarily decrease the fill factor FF and thus reduce the efficiency h. |
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2. While in normal "electrical" life, "milliohms"
hardly count, a few mW serial resistance are enough to make your solar cell measurable
worse. |
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3. Given the specific resistivity of good metals of r
» 2 µWcm, a Cu wire of 1 cm length and
1 mm2 cross section has a resistance of R = 2 mW. The cross sectional
area of the grid metallization on a solar cell is < 1 mm2, which means we
have a real and unavoidable problem with series resistances of real solar cells! |
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Here is a plot of the IV characteristics of a typical
solar cell with 4 different shunt resistances RSH. |
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Everything else has been kept "ideal". This means that the series resistance
RSE is now close to zero. |
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Again, without looking a the (numerically) calculated figure,
we can easily deduce qualitatively what is going to happen. |
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Ueff = U is always true. For Ueff = U = 0 V
all characteristics must run through ISC since the term Ueff/RSH
is zero. |
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Otherwise, for any voltage U in reverse
and forward direction we have a current ISH = Ueff/RSH
that must be added to the diode current and thus shifts the total current upwards (towards
larger values (-1 is larger than -2!) and thus decreases its magnitude in the fourth quadrant by just Ueff/RSH. The flat
part of the ideal characteristic thus turns into a straight line with slope 1/RSH |
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In the fourth quadrant, where it counts, we will loose voltage and
fill factor and thus severely reduce the efficiency h. |
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We also have a reverse current increasing linearly with the reverse voltage - very bad in
a module! |
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All of this is exactly what the calculated figure shows- taking into account the
"Ohmic" straight line centered at ISC we could have derived most of the graph above without
any quantitative calculations |
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We now can draw several conclusions: |
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1. The efficiency h is proportional to the product
of ISc · UOC · FF. As long as RSH
is not too small (>» 1W) for the example given, shunts
are not too bad. Real short circuits < » 1W, however,
are disastrous for the efficiency. |
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2. Since the pn-junction is very large and extends all the way out to the edge of the solar cell, we must expect that local short circuits happen. The rather difficult
question coming up now is how a few local short circuits affect the global
solar cell. |
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Here is a plot of the IU characteristics of a typical
solar cell with deviations from ideality expressed in the ideality factor n and the pre-exponential factors
I1 and I2 |
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Everything else has been kept simple - no shunt or series resistors. This means
that the shunt resistance RSH is very large ("infinity"), RSE
is zero. The ideality factor of the second diode is n2 = 2 or n = 3 (the ideality
factor of the first diode is always n1 = 1 by definition), and the two pre-exponential factors
are I1 = 0,1 µA and I2 = 10 µA as starting values once more,
but also 10 times and 100 times that number. The photo current is 3 A. |
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Without looking a the (numerically) calculated figure, we cannot
easily deduce what is going to happen. |
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Well, looking a the figure, we see that changing the ideality factor of the second diode
from n = 2 to n = 3 does not produce a noticeable change in the characteristics. The simple
reason for this is that in reverse direction the exponentials in the I(U) equation don't matter, and
that in the forward characteristics the ideal diode always "wins" except for small positive voltages. |
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However, the relation between the two diodes is also influenced by the pre-exponential factors.
Divided by the cell area, they were abbreviations for the following current
densities: |
| |
| j1 = |
æ
ç
è |
e · L · ni 2
t · NA |
+ |
e · L · ni 2
t · ND |
ö
÷
ø |
| | |
| |
| |
| j2 = |
æ
ç
è |
e · ni · d(U)
t |
ö
÷
ø |
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Why did we pick j2 so much larger than j1?
We have, in fact, already discussed the relation
j2 / j1 for pn-junctions, even so you probably forgot it all, and found
that j2 >> j1 is unavoidable for Si and other semiconductors with
bandgaps <» 1 eV. This is why the values chosen for the pre-exponential factors
and given above have the relation they have. |
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On the other hand, both factors are functions of variables like the diffusion length L
or the recombination time t, i.e. of crystal perfection; of the doping NDop;
and of the temperature T (via the intrinsic carrier concentration ni). |
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I1 and I2 are thus variables up to a point,
and we want them as small as possible because the currents they cause diminish the photo current and the open circuit voltage.
The figure shows that clearly. Increasing I1 or I2 substantially, decreases
UOC and, for the case of I2, also the fill factor FF. |
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However, they should not be too small, either. If they would be zero, we would just have a
constant photo current and no voltage ever builds up. The values chosen are rather optimal, that's why we called them "ideal". |
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Our basic equation on top contains the temperature explicitly in the two exponentials
and implicitly in the two pre-exponential factors j1 and j2. |
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The two equations right above for these two factors contain ni(T),
the intrinsic carrier density, which grows exponentially with increasing temperature. |
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On top of that, the lifetime t might be temperature dependent
as well as the series and parallel resistors, but we will neglect that here. |
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So what it the total effect of temperature? This is shown below for negligible
resistances and an ideality factor n = 2. |
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What we have is quite clear: As long as IPh does not
depend on temperature (e.g. because we have a very good solar cell where all photo generated carriers are turned into photo
current), the influence of the temperature comes from the exponents of our basic equation and from the (exponentially; via
ni)) temperature dependent j1 and j2 |
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The major effect is that the open circuit voltage decreases a lot (which is bad). |
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Taking into account that IPh might be somewhat temperature dependent
too (via the temperature dependence of the diffusion length, for example), that the series and shunt resistors most likely
will be temperature dependent like most everything else, the situation can become quite complicated. |
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However, the total effect is practically always that the efficiency comes down quite a bit
with increasing temperature - high temperatures are bad for solar cells! |
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This gives at least some comfort to cold and sun-deprived areas like Schleswig-Holstein. We
may not have as much sun as the people in Spain or Sicily, but we don't have to worry as much about keeping our solar cells
cool! |
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© H. Föll (Semiconductor Technology - Script)
8.1.2 Solar Cell Current-Voltage Characteristics and Equivalent Circuit Diagram 
With frame