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Make a solar cell in your kitchen
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http://www.scitoys.com/scitoys/scitoys/echem/echem2.html
It was super, super, super cool, so we thank them for allowing us to post it
at TheSolarPlan.com! This is nifty!
A solar cell is a device for converting energy from the sun into
electricity.
The high-efficiency solar cells you can buy at Radio Shack and
other stores are made from highly processed silicon, and require huge
factories, high temperatures, vacuum equipment, and lots of money.
If we are willing to sacrifice efficiency for the ability to make our own
solar cells in the kitchen out of materials from the neighborhood hardware
store, we can demonstrate a working solar cell in about an hour.
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Our solar cell is made from cuprous oxide instead of silicon. Cuprous oxide
is one of the first materials known to display the photoelectric effect, in
which light causes electricity to flow in a material.
Thinking about how to explain the photoelectric effect is what led Albert
Einstein to the Nobel prize for physics, and to the theory of relativity.
Materials you will need
The solar cell is made from these materials:
A sheet of copper flashing from the hardware store. This normally costs
about $5.00 per square foot. We will need about half a square foot.
Two alligator clip leads.
A sensitive micro-ammeter that can read currents between 10 and 50
microamperes. Radio Shack sells small LCD multimeters that will do, but I
used a small surplus meter with a needle.
An electric stove. My kitchen stove is gas, so I bought a small one-burner
electric hotplate for about $25. The little 700 watt burners probably won't
work -- mine is 1100 watts, so the burner gets red hot.
A large clear plastic bottle off of which you can cut the top. I used a 2
liter spring water bottle. A large mouth glass jar will also work.
Table salt. We will want a couple tablespoons of salt.
Tap water.
Sand paper or a wire brush on an electric drill.
Sheet metal shears for cutting the copper sheet.
How to build the solar cell
My burner looks like this:
The first step is to cut a piece of the copper sheeting that is about the
size of the burner on the stove. Wash your hands so they don't have any
grease or oil on them. Then wash the copper sheet with soap or cleanser to
get any oil or grease off of it. Use the sandpaper or wire brush to
thoroughly clean the copper sheeting, so that any sulphide or other light
corrosion is removed.
Next, place the cleaned and dried copper sheet on the burner and turn the
burner to its highest setting.
As the copper starts to heat up, you will see beautiful oxidation patterns
begin to form. Oranges, purples, and reds will cover the copper.
As the copper gets hotter, the colors are replaced with a black coating of
cupric oxide. This is not the oxide we want, but it will flake off later,
showing the reds, oranges, pinks, and purples of the cuprous oxide layer
underneath.
The last bits of color disappear as the burner starts to glow red.
When the burner is glowing red-hot, the sheet of copper will be coated with
a black cupric oxide coat. Let it cook for a half an hour, so the black
coating will be thick. This is important, since a thick coating will flake
off nicely, while a thin coat will stay stuck to the copper.
After the half hour of cooking, turn off the burner. Leave the hot copper on
the burner to cool slowly. If you cool it too quickly, the black oxide will
stay stuck to the copper.
As the copper cools, it shrinks. The black cupric oxide also shrinks. But
they shrink at different rates, which makes the black cupric oxide flake
off.
The little black flakes pop off the copper with enough force to make them
fly a few inches. This means a little more cleaning effort around the stove,
but it is fun to watch.
When the copper has cooled to room temperature (this takes about 20
minutes), most of the black oxide will be gone. A light scrubbing with your
hands under running water will remove most of the small bits. Resist the
temptation to remove all of the black spots by hard scrubbing or by flexing
the soft copper. This might damage the delicate red cuprous oxide layer we
need to make to solar cell work.
The rest of the assembly is very simple and quick.
Cut another sheet of copper about the same size as the first one. Bend both
pieces gently, so they will fit into the plastic bottle or jar without
touching one another. The cuprous oxide coating that was facing up on the
burner is usually the best side to face outwards in the jar, because it has
the smoothest, cleanest surface.
Attach the two alligator clip leads, one to the new copper plate, and one to
the cuprous oxide coated plate. Connect the lead from the clean copper plate
to the positive terminal of the meter. Connect the lead from the cuprous
oxide plate to the negative terminal of the meter.
Now mix a couple tablespoons of salt into some hot tap water. Stir the
saltwater until all the salt is dissolved. Then carefully pour the saltwater
into the jar, being careful not to get the clip leads wet. The saltwater
should not completely cover the plates -- you should leave about an inch of
plate above the water, so you can move the solar cell around without getting
the clip leads wet.
The photo above shows the solar cell in my shadow as I took the picture.
Notice that the meter is reading about 6 microamps of current.
The solar cell is a battery, even in the dark, and will usually show a few
microamps of current.
The above photo shows the solar cell in the sunshine. Notice that the meter
has jumped up to about 33 microamps of current. Sometimes it will go over 50
microamps, swinging the needle all the way over to the right.
How does it do that?
Cuprous oxide is a type of material called a semiconductor. A semiconductor
is in between a conductor, where electricity can flow freely, and an
insulator, where electrons are bound tightly to their atoms and do not flow
freely.
In a semiconductor, there is a gap, called a bandgap between the electrons
that are bound tightly to the atom, and the electrons that are farther from
the atom, which can move freely and conduct electricity.
Electrons cannot stay inside the bandgap. An electron cannot gain just a
little bit of energy and move away from the atom's nucleus into the bandgap.
An electron must gain enough energy to move farther away from the nucleus,
outside of the bandgap.
Similarly, an electron outside the bandgap cannot lose a little bit of
energy and fall just a little bit closer to the nucleus. It must lose enough
energy to fall past the bandgap into the area where electrons are allowed.
When sunlight hits the electrons in the cuprous oxide, some of the electrons
gain enough energy from the sunlight to jump past the bandgap and become
free to conduct electricity.
The free electrons move into the saltwater, then into the clean copper
plate, into the wire, through the meter, and back to the cuprous oxide
plate.
As the electrons move through the meter, they perform the work needed to
move the needle. When a shadow falls on the solar cell, fewer electrons move
through the meter, and the needle dips back down.
A note about power
The cell produces 50 microamps at 0.25 volts.
This is 0.0000125 watts (12.5 microwatts).
Don't expect to light light bulbs or charge batteries with this device. It
can be used as a light detector or light meter, but it would take acres of
them to power your house.
The 0.0000125 watts (12.5 microwatts) is for a 0.01 square meter cell, or
1.25 milliwatts per square meter. To light a 100 watt light bulb, it would
take 80 square meters of cuprous oxide for the sunlit side, and 80 square
meters of copper for the dark electrode. To run a 1,000 watt stove, you
would need 800 square meters of cuprous oxide, and another 800 square meters
of plain copper, or 1,600 square meters all together. If this were to form
the roof of a home, each home would be 30 meters long and 30 meters wide,
assuming all they needed electricity for was one stove.
There are 17,222 square feet in 1,600 square meters. If copper sheeting
costs $5 per square foot, the copper alone would cost $86,110.00 USD. Making
it one tenth the thickness can bring this down to $8,611.00. Since you are
buying in bulk, you might get it for half that, or about $4,300.00.
If you used silicon solar panels costing $4 per watt, you could run the same
stove for $4,000.00. But the panels would only be about 10 square meters.
Or, for about a dollar, you can build a solar stove out of aluminum foil and
cardboard. For about $20, you can build a very nice polished aluminum
parabolic solar cooker.
Once again, TheSolarPlan.com thanks http://www.scitoys.com/scitoys/scitoys/echem/echem2.html
for sharing this article with us!
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