Potential of Infinite Sheets of Charge and Conducting Slab

In summary, an infinite sheet of charge with uniform charge density is located at x = 21.0 cm. Another infinite sheet of charge with uniform charge density is located at x = 8.5 cm. An uncharged infinite conducting slab is placed halfway in between these sheets. V(P) - V(S) is 1512.71 V.
  • #1
Gee Wiz
137
0

Homework Statement



An infinite sheet of charge is located in the y-z plane at x = 0 and has uniform charge denisity σ1 = 0.3 μC/m2. Another infinite sheet of charge with uniform charge density σ2 = -0.33 μC/m2 is located at x = c = 21.0 cm.. An uncharged infinite conducting slab is placed halfway in between these sheets ( i.e., between x = 8.5 cm and x = 12.5 cm).
What is V(S) - V(P), the potential difference between point P and point S, located at (x,y) = (16.75 cm, -12.5 cm)? (point P is at 4.25 cm, 0 cm)


Homework Equations


no quite sure



The Attempt at a Solution


So, i thought that the electric field would be constant between the two plates. But, apparently it's not (which i still don't fully understand). Also, i realize that i can basically ignore the thick slab since it has a net of 0 charge. I got v(p) to be 1512.71, but i do not know how to go about getting v(s). Or rather the e field at s would be a good start. I know the e field at p is 35593.2.
 
Physics news on Phys.org
  • #2
Hello, Gee Wiz. Welcome to PF!

Have you learned about electric fields inside of conducting materials for electrostatic conditions?
 
  • #3
um...you mean like induced charge? (i thought that was for spheres)..or did i miss your question?
 
  • #4
Have you learned about the magnitude of E inside a conductor for electrostatics? There's a general fact about this that applies to all conductors.
 
  • #5
Oh, i think i know what you are referring to. That the e field within a conductor's metal is 0. ya?
 
  • #6
ya ya
 
  • #7
alright, I'm not quite sure how that helps here. I thought i could basically just ignore that slab since it has a net of 0
 
  • #8
If you didn't have the slab, how would you get the potential difference?
 
  • #9
take the e-field that i found at p times the difference between the distance of the two points.
 
  • #10
When you take the distance between the two points, be careful. Do you take the actual displacement between the points, or only the component of the displacement parallel to the field?

With the slab in place, there is no electric field in the region of the slab. Should the potential change when going through the slab?
 
  • #11
Sorry, when i said distance between the two points i meant horizontal distance.

I think i am struggling with the slab notion. I'm pretty sure that the e-field and therefore the potential charge in the slab would be zero. I found in an earlier part of this problem the charge density on either side of the slab (-.315uc/m^2 and .315uc/m^2). Does that play a role here?
 
  • #12
Gee Wiz said:
Sorry, when i said distance between the two points i meant horizontal distance.
Good.
I think i am struggling with the slab notion. I'm pretty sure that the e-field and therefore the potential charge in the slab would be zero.
I don't know what "potential charge" means.
I found in an earlier part of this problem the charge density on either side of the slab (-.315uc/m^2 and .315uc/m^2). Does that play a role here?

Not directly. The key idea is that potential difference between points is due to electric field in the region between the points. As you move around in a region of electric field, the potential changes. Going "downstream" in the direction of the field causes the potential to decrease. Going against the field increases the potential.

Suppose that you had two points of space where there is no electric field in the region between the points. How would the potential at the two points compare? For example if V = 100 V at one point, what would it be at the other point?

Can you apply this to two points of the slab? Say, point A on the left surface of the slab at x = 8.5 cm and point B on the right surface at x = 12.5. What is V(A) - V(B)?
 
  • #13
i think i meant electric potential (since e field is zero).

If there is not electric field in the region then i would assume that the other point would also be 100V. I think?

V(A)-V(B) would be 0 since there is no e field in the slab..?
 
  • #14
That's right. The potential has the same value for all points of the slab.
 
  • #15
Alright so, would i just shrink the distance (horizontal distance) by 4cm. since that is the length of the slab. so instead of being 16.75cm away from the furthest charge it is only 12.75cm away?
 
  • #16
Yes. Or, equivalently, shrink the horizontal distance between P and S by 4 cm.
 
  • #17
Awesome, two things: i got the right answer from that and your explanation was really helpful for other things in my course. I really appreciate it. Have a super Monday!
 
  • #18
Good work!
 

1. What is an infinite sheet of charge?

An infinite sheet of charge is a theoretical construct used in physics and mathematics to represent a flat, two-dimensional surface with an infinite amount of electric charge distributed uniformly across it. This means that the charge is spread out evenly across the entire surface, with no concentration in any particular area.

2. How does an infinite sheet of charge behave?

An infinite sheet of charge behaves similarly to a point charge, as the electric field produced by the sheet is constant and perpendicular to the surface at all points. This means that the electric field lines are parallel and evenly spaced, and the strength of the field is the same at all points.

3. What is the potential of an infinite sheet of charge?

The potential of an infinite sheet of charge is directly proportional to the distance from the surface, and is given by the formula V = σ/2ε0, where σ is the surface charge density and ε0 is the permittivity of free space. This means that the potential decreases as you move further away from the sheet.

4. What is a conducting slab?

A conducting slab is a three-dimensional object made of a material that allows the free flow of electric charges. This means that the charges within the slab can easily move in response to an applied electric field. Examples of conducting materials include metals, saltwater, and the human body.

5. How does a conducting slab affect the electric field of an infinite sheet of charge?

A conducting slab placed near an infinite sheet of charge will create an electric field that is perpendicular to both the sheet and the surface of the slab. This field acts to cancel out the electric field of the sheet, resulting in no net electric field within the slab. This is known as the "shielding effect" of a conducting slab.

Similar threads

Charge Density on a Conductive Slab
    • Introductory Physics Homework Help
Replies
1
Views
2K
I Thought I Understood Gauss' Law (Sheets)
    • Introductory Physics Homework Help
Replies
26
Views
576
Infinite Sheets of Charge and Conducting Slab
    • Introductory Physics Homework Help
Replies
4
Views
20K
Electric Field Between Two Infinite Sheets of Charge
    • Introductory Physics Homework Help
Replies
2
Views
15K
Electric field between conducting and non-conducting sheets
    • Introductory Physics Homework Help
Replies
9
Views
3K
Charge rearrangement on conducting spheres
    • Introductory Physics Homework Help
Replies
21
Views
2K
Finding electric potential of an infinite line charge at z axis
    • Introductory Physics Homework Help
2
Replies
64
Views
2K
I Electric Field Shielding by Conducting Sheets
    • Electromagnetism
Replies
3
Views
988
Help with Mathematical Description & Calculations of Space Charge Density
    • Introductory Physics Homework Help
Replies
5
Views
765
MIT OCW, 8.02 Electromagnetism: Potential for an Electric Dipole
    • Introductory Physics Homework Help
Replies
1
Views
890

Hot Threads

Recent Insights

Back
Top