What is going on when a solar cell goes into reverse bias?

In summary, when a PN doped crystalline silicon cell is shaded, the current flow in the cell is limited by the number of photons striking it. This means that if a cell is completely shaded, no current will flow through it. In a series string of cells, the voltage across the shaded cell will be zero, while the other cells will have a voltage close to the equivalent diode voltage. The voltage across each cell will add up to the total voltage of the solar module. A diode does not follow Ohm's law, but in this scenario, it acts as a current source and sets up a reverse bias on the shaded cell.
  • #1
ecvolt
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I would like to understand exactly what happens when a PN doped crystalline silicon cell is shaded.Lets assume we have ten solar cells wired together in a series string.That there is plenty of sunlight on the first nine cells but cell ten is completely shaded.Lets say the forward bias of each solar cell is .5 volts let's say the conventional current is moving from anode to cathode and Electron flow is cathode to anode.This would make the anode more positive {more holes} than the cathode {more electrons}When current is flowing in the first nine solar cells at a forward bias how does the tenth cell reverse in bias {now the anode is less positive and the cathode is more positive} ? Do the other nine cells which are getting plenty of photons from the sun also go into reverse bias or just the shaded cell? Is the current flow of electrons and holes in the tenth cell the shaded one going in the opposite direction of the other nine ? What causes the shaded cell to create extreme heat?Lets assume we have no by pass diodes in this ten celled string.lets assume this collection of solar cells is a solar module Thank you ecvolt.
 
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  • #2
Current through each cell will be limited by the number of photons that strike it. So the output of several solar cells in series is limited by illumination of the most shaded cell. If you have 9 cells receiving light and the 10th one does not, you will not get any current flowing. You'd get the same effect if you just put a diode "wrong way" after 9 cells. The 9 illuminated cells will set up a voltage that reverse-bias the 10th, and no current will flow.
 
  • #3
Thank You.Are you saying that cells 1-9 are still in a forward bias state and the shaded cell is in a reverse bias state? I am not sure of what you mean "the nine illuminated cells will set up a voltage that reverse-bias the 10th and no current will flow"To me the fact that the 10th cell is shaded means that the depletion zone at the PN junction of cell 10 has widened and no current will flow thru cell 10 Thanks ecvolt
 
  • #4
Cells 1-9 are going to be near the diode forward voltage, so yes, they are going to behave as forward-biased.
To me the fact that the 10th cell is shaded means that the depletion zone at the PN junction of cell 10 has widened and no current will flow thru cell
The depletion zone will be widened due to applied voltage from other cells. But yes, otherwise, that's what happens.
 
  • #5
If the cells are connected neg to positive neg to positive etc. would that be like connecting diodes cathode to anode cathode to anode etc.?what would be the voltage between cell nine and cell 10? Thank You ecvolt
 
  • #6
There would be no voltage between cells. Just across cells. Here is an image showing equivalent cell.

275px-Solar_cell_equivalent_circuit.svg.png


You can picture this without the resistors. Just a current source and diode in parallel. For the 9 illuminated cells, IL will be non-zero. For the last cell, it will be zero. Since the current can't flow through the last cell with IL=0, there is no current flowing through that cell. That means, for every other cell, IL = ID. That means voltage across each cell will be very close to Vd for the equivalent diode. Assuming the circuit is closed, since there is no current across the load, the voltage across cell 10 is minus the sum of voltages across the 9 other cells.

Note that in all of this, I am ignoring the possibility of a breakdown. With 9 cells, you might actually have enough voltage for breakdown at the 10th cell.
 
  • #7
Would the anode of cell nine be connected to the cathode of cell ten?And would the voltage at the anode of cell 9 be 4.5 volts and seeing that the cathode of cell ten is connected to cell 9 would the voltage also be 4.5 volts at the cathode of cell 10? then what would be the voltage at the anode of cell 10?Thanks ecvolt
 
  • #8
When I take a dc multi meter and read a voltage open circuit of say of 37 volts DC on a solar module comprised of 60 solar cells wired in series am i reading the additive voltage drop of all 60 cells ? so the voltage drop across each cell would approximately, . 616 volts Thank you ecvolt
 
  • #9
ecvolt said:
Would the anode of cell nine be connected to the cathode of cell ten?
Yes. Well, in one possible arrangement, depending which side you count 1-10 from.
ecvolt said:
And would the voltage at the anode of cell 9 be 4.5 volts and seeing that the cathode of cell ten is connected to cell 9 would the voltage also be 4.5 volts at the cathode of cell 10?
4.5V relative to what? Voltage only makes sense as differential.
ecvolt said:
then what would be the voltage at the anode of cell 10?Thanks ecvolt
That depends entirely on how you close the circuit. If you leave it open, voltage across cell ten will be zero. If you close the circuit across a resistive load, since there is no current, the voltage across cell ten must cancel voltage across all other cells.
ecvolt said:
When I take a dc multi meter and read a voltage open circuit of say of 37 volts DC on a solar module comprised of 60 solar cells wired in series am i reading the additive voltage drop of all 60 cells ? so the voltage drop across each cell would approximately, . 616 volts
Yes.
 
  • #10
I want to thank you for helping me.Perhaps you can check this post tomorrow I am gone to post a new scenario .It was a big help when you said there is no voltage between cells just across cells Thank You ecvolt
 
  • #11
Does a diode follow Ohms law? How can you calculate the resistance of a solar cell in the forward bias ? If the forward voltage bias of a solar cell is .616 and the current runnig thru the solar cell is 5 amps would the forward bias resistance be .1232 ohms. Thanks ecvolt
 
  • #12
ecvolt said:
Does a diode follow Ohms law?
Not at all.
How can you calculate the resistance of a solar cell in the forward bias ?
While you can define effective resistance, you don't really need it. It's simply not how you would compute current through a cell.

Lets say you have an ideal solar cell that gives you 0.5V. You connect two of them in series, and attach a 100 Ohm load. Let's also say that the two cells are not evenly illuminated. Say first cell gets enough light for IL=17mA, and second cell IL=12mA. (See diagram in previous post.) First of all, what is the current through the load? Well, the two cells apply 1V combined, so the current through the load will be 10mA. That means that for both cells, IL-ID = 10mA. This tells you that ID will be 7mA and 2mA respectively for the two cells. Notice that from outside this just looks like a battery supplying 10mA at 0.5V. The fact that this is a solar cell has not become relevant yet.

Now, suppose the illumination on first cell decreased, and now the IL=7mA. For second cell, we still have IL=12mA. The total current can no longer be 10mA, because that would require negative value for ID for the first cell. Because it's a diode, you'll have ID=0 instead. That means you'll have total current of 7mA through both cells and the load. At 100 Ohm, that puts total voltage at 0.7V. How do these 0.7V distribute between the two cells? Well, ID for second cell is now 5mA. That means the voltage across the diode is VD, which is the same 0.5V. So the second cell is still at 0.5V, and that leaves first cell at 0.2V. Notice that if illumination drops further, the voltage across first cell can change sign, and start opposing voltage across the second cell.

When the amount of light that hits the cell is insufficient for the current you are trying to draw, the voltage across the cell drops. It behaves as if it has high internal resistance, not unlike a rundown battery.

All of this assumed ideal cell, however, which can be visualized as just a current source and a diode. A real photovoltaic cell will also have sources of Ohmic resistance. See the diagram. In a good cell, resistor in parallel with diode will have high resistance, and resistor in series will have low resistance.
 
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  • #13
OK are you saying that cell 1 gets a light generated current of 17 ma and cell 2 gets a light generated current of 12ma? How did you calculate the current through the load of 10ma? I can see the 1volt part of the equation{.5volts plus .5volts=1 volt but not sure how you got the 10ma . Does Il mean light current generated or current of the load? Is Id mean the current through the diode?I rely appreciate your Patience ! I am a electrician with limited electronics knowledge I am getting this but I have to move slow Thanks ecvolt
 
  • #14
Yes, ID is current through the diode. It's opposite in direction to light generated current. You can think of it as sort of a relief valve that prevents the voltage building up in the cell past whatever output voltage it's meant to have.

10mA is the current through the load. V/R. Nothing tricky. But the current flowing in and out of every junction must be the same. That means that 10mA flowing through the load are the same 10mA flowing out of the second solar cell, which must be equal to IL-ID. That means current between the two cells is also 10mA. And that means that the same relation is true for the first cell. Which finally allows you to match the same 10mA flowing out of the load and back into the first cell.

Basically, all of these are just applications of Kirchoff Laws. There is nothing terribly strange going on with solar cells with the exception of there being a constant current source, which you might not be used to. Once you just accept that it's there and use Kirchoff Laws systematically, you can work out the rest.
 
  • #15
OK due to Kirchoff laws of current the current in a series circuit is the same for solar cell one and solar cell 2 I got that part.Is it the resistance of the load that determines the current flow in the circuit or the lowest iradiance of the individual cells that determines the amount of current flowing .Lower iradiance means less photons which mean less electron hole pairs which mean less current flow through the cell I think? Thanks ecvolt
 
  • #16
When you said " Id is current through the diode.It's opposite in direction to light generated current" Are you referring to the fact that hole movement in a pn junction is in one direction and electron movement is in the opposite direction. Or are you referring to something else thanks ecvolt
 
  • #17
when you said "that means that for both cells , Il-Id=10 ma" are you saying Il minus Id= 10ma. are you saying Il and Id =10ma thanks
 
  • #18
ecvolt said:
When you said " Id is current through the diode.It's opposite in direction to light generated current" Are you referring to the fact that hole movement in a pn junction is in one direction and electron movement is in the opposite direction. Or are you referring to something else
No, the actual conventional current is in the opposite direction. Light pushes electrons from anode to the cathode. But if the voltage across is high enough, electrons will start flowing back from cathode to anode, as they would with an ordinary diode. The conventional current is opposite, of course. The light current is from cathode to anode, and diode current is from anode to cathode.
Is it the resistance of the load that determines the current flow in the circuit or the lowest iradiance of the individual cells that determines the amount of current flowing.
Both. Basically, whichever of the two is the limiting factor. If the total current will be limited by the light current in the least illuminated cell, then the voltage of your assembly will drop so that the V=IR still works for the load. Otherwise, V is just sum of VD of individual cells, and the limiting factor is the current through the load due to that voltage.
Il-Id=10 ma" are you saying Il minus Id= 10ma
This one, yes. The difference of the two currents must be equal to total current. The reason it's difference and not the sum is because IL and ID are assumed to have opposite direction. Just a convention thing.
 
  • #19
So we have two currents light generated current and diode current that are involved in the circuit ?Is the light current generated by the photons and is the diode current derived from voltage drop over the solar cell which is acting like a diode
 
  • #20
Correct. Keep in mind, though, that this is a description from equivalent circuit, where the current source and the diode are treated as two separate elements.

In reality, both processes are happening within the same diode that makes up the photovoltaic cell. That means that you won't really have two separate currents flowing two separate paths, but rather a net current that looks like the difference of the two.
 
  • #21
OK I am getting there thanks to you! Could i contact you with my personal e mail address?
 
  • #22
OK if we have a closed circuit of solar cells in series with a inverter in the circuit would the inverter constitute the load in the circuit ?
 
  • #23
I sent you a private message but it came back and said your box is full thanks ecvolt
 
  • #24
Yes, inverter will act as a load, but its effective resistance will depend on what you connect to it.
 
  • #25
would you happen to know were a electrical contractor such as myself could hire a on-line tutor for the subject we are talking about thanks ecvolt
 
  • #26
does the current flow in the diode have to do with the minority carriers through the pn depletion zone
 
  • #27
question#1 If cell number ten is shaded than Il would be zero for that cell is that correct ? question #2 What would be the Id for cell number ten ? question #3 Also if Il is zero for cell ten than Il would be zero for the other nine cells is that correct?Lets assume the cells are in a closed circuit with th 100 ohm load
 
  • #28
ecvolt said:
does the current flow in the diode have to do with the minority carriers through the pn depletion zone
No. The diode current occurs when it's in forward bias, which happens if the voltage across the cell is high enough. I mean, realistically, yeah, you have to deal with minority carriers, etc. But you can do a very good estimate by ignoring all of that. You can assume the diode to be perfect, with absolutely no current flowing unless you have sufficient forward bias.

question#1 If cell number ten is shaded than Il would be zero for that cell is that correct ? question #2 What would be the Id for cell number ten ? question #3 Also if Il is zero for cell ten than Il would be zero for the other nine cells is that correct?Lets assume the cells are in a closed circuit with th 100 ohm load
1) Yes.
2) In the same situation and with other cells illuminated? Nothing. The diode will be reverse biased, and so no current will flow through it.
3) No. The net current through each cell will have to be zero. But the IL depends only on the amount of light a cell receives. If no current can flow, then ID must be equal to IL so that net current is zero. Like I said, you can think of it as a relief valve.


As for tutoring, check at local universities. There are usually graduate students who need money and are happy to tutor. Electrical engineering grad student is probably your best bet. But you might be able to find somebody in physics as well.
 
  • #29
OK then #1 each of the ten individual cells will have there own Il an ID? #2 When the ten cells are connected in series the cell with the least amount of iradiance will determine the amount of current flow in the CIRCUIT? #3 If cell number ten is completely shaded and cells 1 through 9 are not and all cells are connected in a series string that would be the equivalent of connecting diodes 1 through 9 in a forward bias{anode to cathode } BUT cell number ten would be the equivalent of a diode in reverse bias so cell number 10 would be the equivalent { we don't physically change it}connecting the cathode of cell nine to the cathode of cell 10?#4 Due to the reverse bias created by cell number 10 the current will stop flowing in the circuit because cell number ten acts as a one way valve blocking the flow? Thank you
 
  • #30
Thank you again for hanging in there with me on this subject!It was extremely hard for me to find some one to talk to me about this subject so i am very gratefully for your time and Patience. One concept I am trying to grasp is What is creating the voltage on the solar cell to forward bias the cell? I understand if you connect a battery (which is a voltage source) to a diode you can create either a forward bias ( battery positive to diode anode and battery negative to diode cathode) or a reverse bias (Battery negative to diode anode and battery positive to diode cathode) But what I don't understand is a photo cell is a Current source NOT a voltage source.How is the voltage established across the solar cell??When we say solar cell are we relay talking about the voltage across the PN junctions depletion zone which was established when we introduced the doping of impurities into the silicon solar cell.Were is the voltage coming from since we are not putting a battery to the solar cell Thank you
 
  • #31
A (non-perfect) current source driving any load with a greater than zero resistance will have a voltage. It's simple ohms law for circuits.

http://www.eere.energy.gov/basics/renewable_energy/semiconductors.html

To separate electrical charges, crystalline silicon cells must have a built-in electric field. Light shining on crystalline silicon may free electrons within the crystal lattice, but for these electrons to do useful work—such as provide electricity to a light bulb—they must be separated and directed into an electrical circuit.
 
  • #32
Thank you.can you tell me if the questions #1 through# 4 in post #29 are true or not.Also I believe the force field across the depletion zone which is free of charged carriers is were the voltage of the solar cell is established thanks ecvolt
 
  • #33
Hello K^2 can you also please comment on posts #29 ,#30,#32 thanks
 
  • #34
Picture a capacitor. Imagine that every time a photon comes in, you take an electron from one plate, and move it to another. Always in the same direction. Can you see that electrons being moved that way give you a current? That's your IL. Can you see how the charges displaced that way will give you a voltage across said capacitor? It's kind of like that fora cell.

However, if you don't connect such a cell to anything, as more and more electrons are moved across, and none of them have a way to return, the voltage will grow without a bound. A real solar cell is a diode, which will act as a relief valve. Once the voltage across the cell gets too high, it allows electrons to flow back through it until the voltage is normalized. That return current is the ID.

If you shade one of the cells in a closed circuit, it will not have IL to build up the voltage. In fact, it will not be able to carry charges across at all. So the charges trying to go around the circuit and return to the other 9 cells will bunch up on cell 10 and create the potential difference in the wrong direction, reverse-biasing the diode. All 10 are still connected anode to cathode. It's the opposite sign of voltage differential that will cause cell 10 to have reverse bias. The diode doesn't flip.

For example, if your 9 cells have voltage of 0.5V across each, and you closed the circuit across some load with cell 10 being shaded, voltage across cell 10 will be -4.5V, because the voltages going around a closed loop in a circuit have to add up to 0V. Since there is no current through the load, there is no voltage across it. On the other hand, when all 10 cells receive enough light to drive a current, you get 0.5V across each cell, and -5V across the load.

And again, the least shaded cell only limits the current if the load does not. See the first example I showed with 17mA and 12mA. The 12mA would be the limiting current, but because the entire circuit only takes up 10mA, it doesn't matter. If the total current through your load is 10mA, then total current through each of the cells is 10mA, so as long as each IL is higher, it doesn't matter which cells are more or less shaded. If one or more of the cells doesn't have IL high enough to drive 10mA across, the voltage across these cells will drop, and the total current will be limited by the least IL.

And yes, of course, each cell will have its own IL and ID.
 
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  • #35
K^thank you ever so much! I just ordered a book called Applied Photovoltaics third edition by Stewart R Wenham.I am gone to read it front to back in hopes to understand the subject of how the solar cell works. YOU HAVE GIVEN ME A VERY GOOD EDUCATION ON THIS SUBJECT! I am sure I will have some more questions in the future and perhaps you would look at them THANK YOU ecvolt
 

1. What is reverse bias in a solar cell?

Reverse bias is a condition in which the positive terminal of a power source is connected to the n-type semiconductor layer of a solar cell, while the negative terminal is connected to the p-type layer. This causes the flow of current to be opposite to the normal direction, resulting in a decrease in the efficiency of the solar cell.

2. How does reverse bias affect the performance of a solar cell?

When a solar cell is in reverse bias, the flow of current is reduced due to the depletion region between the p-type and n-type layers becoming wider. This leads to a decrease in the efficiency of the solar cell, as less energy is converted into electricity.

3. Why would a solar cell be put into reverse bias?

Solar cells are typically put into reverse bias for testing purposes. By applying a reverse bias, scientists can measure the leakage current and determine the quality of the solar cell. It can also be used to study the behavior of the depletion region and the effects of different materials on the solar cell's performance.

4. Can reverse bias damage a solar cell?

Reverse bias can potentially damage a solar cell if the voltage applied is too high. This can cause the breakdown of the depletion region, resulting in a large flow of current that can damage the solar cell. However, if the reverse bias is kept within a safe range, it should not cause any damage.

5. How can reverse bias be used to improve the performance of a solar cell?

Reverse bias can be used to improve the performance of a solar cell by reducing the recombination of charge carriers. This is because the wider depletion region in reverse bias acts as a barrier, preventing the recombination of electrons and holes. This can result in a higher efficiency of the solar cell when it is switched back to forward bias.

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