procedure sheet for the experiment " SOLAR CELL"

within the p-n junction , the excess minority carriers thus generated diuse
to the junction where they are carried across and become majority carriers.
The holes and electrons generated on either side of the junction move to-
wards opposite side of the junction. If the junction is now open circuited
the majority carrier excess charge will build on both sides of the junction
tending to lower the build in voltage to some value as shown in gure. This
charge in build in voltage i.e v0 appears as a measurable potential dierence
across the junction, which there by behaves as a source of voltage v0.
If the external circuit is closed, the current will therefore ow there in.
This current will continue as long as there is diusion of excess electrons
from n-side and excess holes from p-side. That means the current ow as
long as the semi-conductor regions are illuminated. In most photovoltaic
applications, the radiation is sunlight and the devices are called solar cells.
In the case p-n junction solar cell, illuminating the material creates an elec-
tric current as excited electrons and remaining holes are swept in dierent
directions by the build in electric eld of the depletion region.
FORMULA :
Eciency():
In a solar cell , the light energy is converted into electrical energy. The
fraction of the light energy converted into electrical energy is the eciency
of the solar cell.
It is given by,=pmpp=Ac:E
WhereAc= surface area of the solar cell
E=w=d
2
= light intensity in Wm
2
W = power of the light source = 60W
d = distance between the source and the cell.
For the given solar cell,
Ac=r
2
r = radius of the solar cell
FILL FACTOR:
This is the measure of the number of photo junction inside the solar cell
which is eectively contributing to the photo current.Also,it can be dened
as the ratio of maximum obtainable power to the product of the open-circuit
voltage and short-circuit current.Since not all the junctions are eective in
the photo voltaic phenomenon. Hence the ll factor decides amount of
junction contributions.
If all the junctions participate FF=1 Otherwise FF<1.
Fill Factor is given by,
FF=Ac.E/Isc.Voc
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CIRCUIT DIAGRAM:
PROCEDURE:
Set up the circuit as shown in the gure. The solar cell power supply
is connected to the bulb. The supply and cooling fan are switched on
the solar cell is kept at a distance d from the source.
The rheostat is shorted and the short circuited current is noted (Isc
approx 50 mA).
Both the terminals of the rheostat are disconnected from the ammeter
voltmeter junction and the open circuit voltage is noted in the mille
voltmeter (Voc approx 500 mV).
By varying the resistance values as 10 ohm, 22 ohm, 47 ohm, 56 ohm,
68 ohm, ..upto 1 kilo ohm correspondingly note down the values of
voltage and current; power is calculated
Calculate and record the Pmpp value from the above table. Also
calculate the eciency and ll factor.
Draw a curve with voltage along axis and current along y axis to get
the characteristics of the solar cell. Draw one more graph between
power and voltage to show power variation.
Repeat the experiment for at least three more distances.
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Tabular column
Model graphsPrecautions
Light from source should fall vertically on the solar cell.
Short circuits should not be done for a longer duration. While taking
down the reading of Isc leads to damage permanently.
RESULT :
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