Surface charge induced in conductor by point charge

In summary: Okay again...(1) The expression I gave is the magnitude of the perpendicular component of the electric field at the surface of the plate due to the positive point charge (the horizontal component can be ignored by making the height of the pill-box vanishingly small). r is the distance between the charge and the point on the plate.This is not actually a problem. In fact, it's just what you need to calculate the field due to the point charge.
  • #1
jdstokes
523
1

Homework Statement



Find the surface charge induced on an infinite conducting plate by a point charge +q at a distance a from the plate.

The Attempt at a Solution



As you probably know, this problem can be solved using the well-known fact that the induced electric field is equivalent to replacing the conductor by a negative point charge -q placed diametrically oposite to +q. I am trying to solve the problem without using this fact.

Can you spot the error in this logic?

The electric field at a point on the surface due to the point charge +q is given by [itex]\frac{q}{4\pi\epsilon_0 }\frac{a}{r^3}[/itex].

Since the plate is conducting, the surface electric field is [itex]\frac{\sigma}{\epsilon_0}[/itex].

Application of Gauss's law to a pill-box of negligible height and area A, gives

[itex]\oint \vec{E} \cdot d\vec{a} = \frac{Q_\mathrm{encl}}{\epsilon_0}[/itex]

[itex]-\frac{q}{4\pi\epsilon_0}\frac{a}{r^3} A - \frac{\sigma}{\epsilon_0}A = \frac{\sigma}{\epsilon_0}A \implies[/itex]

[itex]\sigma = -\frac{qa}{8\pi\epsilon_0 r^3}[/itex].

Correct answer:

[itex]\sigma = -\frac{qa}{2\pi\epsilon_0 r^3}[/itex].

Edit: Corrected typos.
 
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  • #2
I see three problems here...

(1)the field due to the point charge is not [tex]\frac{q}{4\pi\epsilon_0 }\frac{a}{r^3}[/tex] (in fact, this isn't even the correct magnitude for the field)

(2)the electric field at the surface to due the induced surface charge is really undefined...on one side of the plane, it points in one direction with a magnitude [tex]\frac{\sigma}{2\epsilon_0}[/tex] and on the other side, it has the same magnitude, but points in the opposite direction!...So when you talk about the field at the surface...are you talking about the field above the surface? the field below? the average field?...The answer is that the field at the surface is really infinite (undefined)...

(3) the third problem is that while the field on either side of the plane due to just the induced charge is uniform over your gaussian surface, the field due to the point charge is not and so [tex]\oint \vec{E}_{\text{point charge}} \cdot d\vec{a} \neq \frac{q}{4\pi\epsilon_0 }\frac{a}{r^3}A[/tex]

PS if the conducting plane is the x-y plane, then the correct surface charge density is [tex]\sigma(x,y) = \frac{-qa}{2\pi (x^2+y^2+a^2)^{3/2}}\neq -\frac{qa}{2\pi\epsilon_0 r^3}[/tex]
 
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  • #3
Thanks for your reply gabbagabbahey.

None of these are actually problems.

(1) The expression I gave is the magnitude of the perpendicular component of the electric field at the surface of the plate due to the positive point charge (the horizontal component can be ignored by making the height of the pill-box vanishingly small). r is the distance between the charge and the point on the plate.

(2) The electric field inside the matirial is zero (since it is a conductor). The expression for the electric field on the exterior is sigma/epsilon_0, not sigma/2epsilon_0. It is well-defined.

(3) This is also not a problem: just take the area intercepted by the Gaussian surface to be sufficiently small that the perpendicular component of the electric field (and the surface charge density) can be considered constant.
 
  • #4
jdstokes said:
Thanks for your reply gabbagabbahey.

None of these are actually problems.

(1) The expression I gave is the magnitude of the perpendicular component of the electric field at the surface of the plate due to the positive point charge (the horizontal component can be ignored by making the height of the pill-box vanishingly small). r is the distance between the charge and the point on the plate.

Okay. (Although you didn't make this clear in your original post :wink:)

EDIT- shouldn't the perpendicular component be [tex]\frac{q}{4\pi\epsilon_0 }\frac{a}{r^3} \cos \theta[/tex] where theta is the angle between the vector from the point charge the the point on the plane, and the vector from the point charge to the center of the plane?

(3) This is also not a problem: just take the area intercepted by the Gaussian surface to be sufficiently small that the perpendicular component of the electric field (and the surface charge density) can be considered constant.

Okay again...

(2) The electric field inside the matirial is zero (since it is a conductor). The expression for the electric field on the exterior is sigma/epsilon_0, not sigma/2epsilon_0. It is well-defined.

errmmm not really...

The plane is considered to be a single infinitesimally thin surface, so it makes no sense to say the field inside the material is zero because the material in this case is infinitesimally thin. You have a single surface; not two distinct surfaces with material in between!

The electric field at the surface is undefined in this case, because it simultaneously points in two directions!

The electric field on either side of the surface, is however well-defined and it has a magnitude of [tex]\frac{\sigma}{2\epsilon_0}[/tex] (you can check your text if you don't believe me about the factor of 2) and points downward below the surface, and upward above it.

When you use your Gaussian pillbox, you have two surfaces (neglecting the sides of the box), and you need to be careful to calculate the flux through both surfaces...as long as your box is of finite thickness, the fact that the field at the surface is undefined won't be a problem...just make sure to place your pillbox so that its top is above the plane, and its bottom is below...
 
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  • #5
I don't know why you think the conductor should have negligible thickness, nor why the charge density should be sigma/2epsilon_0.

You can use a Gaussian surface to easily show it is sigma/epsilon_0. The result you quoted would hold for a non-conducting slab with surface charge e.g.
 
  • #6
I was thinking of an infinite conducting "plane", but now re-reading the question I see you have an infinite conducting "plate"...which can have a non-zero thickness. ...In this case, then yes the field is just sigma/epsilon_0.

However, the perpendicular component of the field due to the charge is still incorrect...you need a cos(theta) there.
 
  • #7
No. because [itex]\cos\theta = a/r[/itex].
 
  • #8
[itex]\therefore E_\perp = E\cos\theta = (q/4\pi\epsilon_0 r^2)(a/r) = qa/(4\pi\epsilon r^3)[/itex]
 
  • #9
Hmmm okay, yes I missed that :redface:...
 
  • #10
So, I wonder why I'm getting the wrong answer.

Could it have something to do with the fact that the problem must be solved self-consistently?
 
  • #11
Are you sure you are looking for the case of a conducting plate with some finite thickness?...the method of images doesn't really work in that case...In the case of a conducting "plane" on the other hand, it does and it gives [tex]\sigma = -\frac{qa}{2\pi\epsilon_0 r^3}[/tex]

Anyways, in the case of the thick conducting slab, the field due to the induced surface charge points upwards so [tex]\oint \vec{E}_{\text{surface}} \cdot \vec{da}=\frac{+\sigma A}{\epsilon_0} \neq \frac{-\sigma A}{\epsilon_0}[/tex]

but you also have a contribution due to the other surface of the slab (the one not enclosed by the gaussian pillbox) since it creates a non-zero field too!

In the case of the conducting "plane" on the other hand, there is only one surface charge density to consider,and it creates a field of strength sigma/2epsilon_0 , and so [tex]\oint \vec{E}_{\text{surface}} \cdot \vec{da}=\frac{+\sigma A}{2\epsilon_0}[/tex]...which will yield your desired answer.
 
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  • #12
Nah, images should work fine for an infinite-thickness slab. In fact, that's the original idea it was proposed for I believe.

Also, the field due to the induced charge doesn't point up (remember a +ve point charge induces a -ve surface charge).

The equations I gave in my original post stand.
 
  • #13
Oh, and the contribution from ``the other side'' is irrelevant because the sheet is infinite so they will never come in contact. Alternatively, just send the other side away to infinity by considering a thick slab.
 
  • #14
Where would you put the image charge for an infinite thickness slab?...you can't have an image charge inside the slab, because it would create a non-zero field there and so it wouldn't satisfy the boundary condition that the field is zero everywhere inside the conductor!
 
  • #15
Using the Gaussian method for the slab of infinite thickness, you would have to consider a slab of finite thickness 'd' and then take the limit as d approaches infinity...the contribution due to the other surface will make a difference.

If you don't include the term due to the other surface, you have: [tex]-\frac{q}{4\pi\epsilon_0}\frac{a}{r^3} A + \frac{\sigma}{\epsilon_0}A = \frac{\sigma}{\epsilon_0}A \Rightarrow -\frac{q}{4\pi\epsilon_0}\frac{a}{r^3} A=0[/tex] which is a contradiction for a non-zero A.
 
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  • #16
jdstokes said:
Nah, images should work fine for an infinite-thickness slab. In fact, that's the original idea it was proposed for I believe.

Also, the field due to the induced charge doesn't point up (remember a +ve point charge induces a -ve surface charge).

The equations I gave in my original post stand.

it does point down, but sigma is negative so [tex]\frac{\sigma}{\epsilon_0}\hat{n}[/tex] is a field that points down...the way you calculated it, you have the field pointing upward.
 
  • #17
Let me see,

Gauss' law is

[itex]-\frac{qa}{4\pi\epsilon_0 r^3} A - \frac{|\sigma|}{\epsilon_0} A = -\frac{|\sigma|}{\epsilon_0} A[/itex].

So it does indeed cancel off. Hmmm, interesting.
 
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  • #18
Yes, and in order to account for that apparent contradiction, in the case of the thick slab, you need to add the flux due to the other surface charge...

However, you may want to reread the original question, because if the answer is supposed to what you said it was, the problem must actually be about an infinitesimally thin slab (aka a plane); and the field due to that is [tex]\frac{\sigma}{2\epsilon_0}[/tex]...which will give you your desired answer.
 

1. How is surface charge induced in a conductor by a point charge?

Surface charge is induced in a conductor by a point charge due to the redistribution of electrons on the surface of the conductor. When a point charge is brought close to a conductor, the electric field of the point charge causes the electrons on the surface of the conductor to move towards or away from the point charge, creating a net charge on the surface.

2. What factors affect the magnitude of the surface charge induced in a conductor?

The magnitude of the surface charge induced in a conductor by a point charge is dependent on the distance between the point charge and the conductor, as well as the material properties of the conductor such as its conductivity and permittivity. Additionally, the magnitude of the point charge itself also plays a role in determining the surface charge induced.

3. How does the induced surface charge on a conductor affect its electric field?

The induced surface charge on a conductor creates an electric field that opposes the electric field of the point charge. This results in a distortion of the electric field in the vicinity of the conductor, causing the electric field lines to curve towards or away from the conductor depending on the direction of the surface charge.

4. Can the surface charge induced in a conductor be controlled?

Yes, the surface charge induced in a conductor can be controlled by altering the distance between the point charge and the conductor, as well as by changing the material properties of the conductor. Additionally, the presence of other charges in the vicinity can also affect the magnitude and direction of the induced surface charge.

5. What are the practical applications of surface charge induction in conductors?

The phenomenon of surface charge induction in conductors has many practical applications, such as in the design of electrostatic shields and capacitors. It is also used in the operation of electronic devices, such as transistors and microchips. Additionally, surface charge induction is an important concept in the study of electromagnetism and is used in various fields of science and technology.

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