Separating capacitor plates: (+) or (-) work?

In summary, the conversation discusses finding the force between two parallel plates in a capacitor as a function of the potential drop across the capacitor. The formula provided for this is F = -dU/dd, which is derived from the concept of work being done. The negative sign is necessary because the force must be exerted in the opposite direction of the force of attraction between the plates. By differentiating the potential energy function with respect to distance, the formula for F(V) is obtained, with the final answer being F(V) = (-ϵ0AV2/2) x (-1/d2).
  • #1
Blehs
15
0

Homework Statement



Consider a parallel-plate capacitor with plates of area A and with separation d. Find F(V), the magnitude of the force each plate experiences due to the other plate as a function of V, the potential drop across the capacitor.

Hint i used
If the plate separation were changed while the voltage was kept constant, the stored energy would change. The force between the plates would be the quantitiy that would be multiplied by the change in the plate separation to obtain the change in energy. In other words,

F= -dU/dd

Im not sure if I am fully understanding this hint. Is the formula they've provided simply Work = force x distance? Besides I am not actually supposed to move the plates, so what would i have to input for the the dd (change in distance) part?

Homework Equations


The Attempt at a Solution



U = (ϵ0AV2)/(2d)

The formula they told me to work out for energy stored in a capacitor.

So I am also feeling quite confused about whether work should be positive or negative.

Because the two plates are oppositely charged, it means that they experience a force of attraction - therefore moving the plates further apart should mean positive work being done right?
However in the hint for this question I am working on, the work is deemed to be negative.

From my experiences with work being done, I've always felt that doing positive work means that some external force has to act upon the object to cause that particular change in position. Therefore for negative work, it is like releasing an object and letting it move by itself without you having to put any extra effort in.

If there is any easy way that people can determine whether work is positive or negative in the context of electric charge then please do tell.
 
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  • #2
Blehs said:
Hint i used
If the plate separation were changed while the voltage was kept constant, the stored energy would change. The force between the plates would be the quantitiy that would be multiplied by the change in the plate separation to obtain the change in energy. In other words,

F= -dU/dd

Im not sure if I am fully understanding this hint. Is the formula they've provided simply Work = force x distance? Besides I am not actually supposed to move the plates, so what would i have to input for the the dd (change in distance) part?
Are you given the potential energy function and then asked to find the force? That hint tells you how to find the force from the potential energy function--you're finding the derivative of U with respect to the distance.

So I am also feeling quite confused about whether work should be positive or negative.

Because the two plates are oppositely charged, it means that they experience a force of attraction - therefore moving the plates further apart should mean positive work being done right?
Right.
However in the hint for this question I am working on, the work is deemed to be negative.
Where does the hint say anything about work being positive?
 
  • #3
Doc Al said:
Are you given the potential energy function and then asked to find the force? That hint tells you how to find the force from the potential energy function--you're finding the derivative of U with respect to the distance.

No i had to work out the function for U myself. It was an earlier part of the hint so i just chucked the equation in.

Doc Al said:
Where does the hint say anything about work being positive?

Ok well starting from the equation F = -dU/dd, i thought that in general, dU would mean change in energy (like u2-u1) and dd means change in distance (d2-d1). Therefore the equation would become U2-U1 = - Force x (d2-d1) which is similar to the work = force x distance equation.

Therefore i thought that the F = -dU/dd equation had somehow been derived from the concept of work being done. That then caused me to ponder why the negative sign was in there.
 
  • #4
Yes, that equation is related to the work being done. The negative sign is because you need to apply a force opposite to the force of attraction to calculate the work done. F is the force between the plates, so -F is the force you must exert.

Read this: http://hyperphysics.phy-astr.gsu.edu/hbase/pegrav.html#pen"
 
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  • #5
Ohhh ok, that makes sense and is simple too - i just thought too much and confused myself i think.

Ok so back to the actual question where I am supposed to find F(V). I differentiated U with respect to d and i got

dU/dd = (-ϵ0AV2/2) x loged

so does F(V) = dU/dd?
 
  • #6
Blehs said:
Ok so back to the actual question where I am supposed to find F(V). I differentiated U with respect to d and i got

dU/dd = (-ϵ0AV2/2) x loged
What's the derivative of 1/x with respect to x?

so does F(V) = dU/dd?
Don't forget the minus sign.
 
  • #7
woops yeah i was thinking of integration.

instead of loged its supposed to be -1/d2

so the two minus signs cancel each other out
Got it correct! thnx heaps for clearing things up a little =]
 

What is the purpose of separating capacitor plates?

The purpose of separating capacitor plates is to create an electric field between them, which can store energy in the form of electric charges.

How does separating capacitor plates affect the capacitance?

Separating capacitor plates increases the distance between them, which decreases the capacitance. This is because the electric field strength decreases with distance, resulting in a smaller amount of charge being stored on the plates.

Is there a preferred orientation for separating capacitor plates?

There is no preferred orientation for separating capacitor plates. The orientation of the plates does not affect the capacitance or the function of the capacitor.

Does separating capacitor plates affect the work needed to charge the capacitor?

Yes, separating capacitor plates affects the work needed to charge the capacitor. Increasing the distance between the plates increases the electric potential difference, which requires more work to overcome and charge the capacitor.

How does the material of the separating plates affect the operation of the capacitor?

The material of the separating plates does not significantly affect the operation of the capacitor. As long as the material is conductive and can maintain a charge, it will function effectively as a capacitor.

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