Calculating Electric Field with Point Charge and Hollow Sphere

AI Thread Summary
When a point charge Q is placed outside a perfectly conducting hollow sphere, the electric field E outside the sphere can be calculated using the formula E = Q/(4πε₀D²), where D is the distance from the center of the sphere. The charge induces a negative charge (-Q) on the inner surface of the sphere to cancel any electric field within the conductor, while a positive charge Q distributes uniformly on the outer surface. The symmetry of the system allows for this simplification, meaning the position of Q only affects the field outside the sphere based on its distance from the center. There is no electric field inside the conductor, confirming that the field outside depends solely on the external charge's position. This understanding is crucial for solving similar electrostatic problems involving conductors.
jimbo007
Messages
41
Reaction score
2
if u have an uncharged,perfectly conducting hollow sphere of thickness t and radius R, and a point charge Q is placed a distance D from the centre of the sphere so that R-t>D, what would the electric field, E, be?
i just treated it the same as if Q was in the centre of the sphere and the electric field lines came perpendicular to the sphere and so

E=\frac{Q}{4 \pi \epsilon_{0}D^2}

anyone got any better ideas?
 
Physics news on Phys.org
jimbo007 said:
if u have an uncharged,perfectly conducting hollow sphere of thickness t and radius R, and a point charge Q is placed a distance D from the centre of the sphere so that R-t>D, what would the electric field, E, be?
i just treated it the same as if Q was in the centre of the sphere and the electric field lines came perpendicular to the sphere and so

E=\frac{Q}{4 \pi \epsilon_{0}D^2}

anyone got any better ideas?
There is no reason to assume that you can do that. One the charge is offset from the center you've changed he symmetry of the situation.

Pete
 
The point charge induces a charge (-Q) on the inner surface as to cancel the field inside the conductor. The remaining induced charge (Q) will distribute itself over the surface of the sphere.
I'm pretty certain it will spread uniformly so that the electric field you got is correct.
 
jimbo007 said:
E=\frac{Q}{4 \pi \epsilon_{0}D^2}
I assume you meant to write:
E=\frac{Q}{4 \pi \epsilon_{0}r^2}
That would be correct for the field for r > R. (r = 0 is the center of the sphere.)

See my answer here: https://www.physicsforums.com/showthread.php?t=37090
 
There is no electric field inside the conductor. The conductor accomplishes this by arranging a layer of charge in an appropriate distribution on the outer surface of the sphere with a total amount equal to -Q. The inner surface of the sphere therefore develops a negative charge deficit equal to this (+Q) and also distributed appropriately (since there is no field inside the conductor). This all results in a negative image charge somwhere below the surface of the sphere, not quite in the center, and not necessarily near the surface, and not necessarily equal to -Q. I don't remember what the expression is off the top of my head; sorry. Look up the "method of images."
 
lol, thanks for the responses guys, very much appreciated
but I'm still completely stumped by the question
just to make it clear i want to find an expression for the electric field outside the sphere (after reading my first post i didnt think my question was very clear)

thanks again
 
jimbo007 said:
lol, thanks for the responses guys, very much appreciated
but I'm still completely stumped by the question
just to make it clear i want to find an expression for the electric field outside the sphere (after reading my first post i didnt think my question was very clear)
What's stumping you? I gave the expression for the field outside the sphere in my first response. Now... to explain why that's the right answer requires a little more...
 
turin said:
There is no electric field inside the conductor.
Right.
The conductor accomplishes this by arranging a layer of charge in an appropriate distribution on the outer surface of the sphere with a total amount equal to -Q.
I believe you have it backwards. The -Q is induced on the inner surface. This surface charge is arranged to exactly cancel the field from the charge within the cavity, thus producing zero field everywhere inside the conductor.
 
i just typed out my response and realized something. i couldn't see the difference between the formula i gave and the formula u gave but now i think i see it.
so by the sounds of it, it doesn't matter where you place the charge Q inside the sphere, E outside the sphere depends on the position only from the centre of the sphere. is this right?
 
Last edited:
  • #10
That is correct.
 
  • #11
Doc Al,
Oops. I read the post too quickly. I was responding under the false impression that the point charge, Q, was placed outside the conductor. Sorry to all.
 

Similar threads

B Electric Field Inside a Hollow Sphere
Replies
5
Views
1K
B Can charges move without a field? How charges redistribute without it?
Replies
16
Views
1K
Electric field external to Conducting Hollow Sphere with charge inside
Replies
23
Views
3K
I Magnetic field when the area of the plates of a capacitor increases
Replies
7
Views
1K
I In ##\nabla\cdot\vec{E}## why can ##\nabla## pass through the integral?
Replies
8
Views
1K
B E. Potential Energy: Uniformly Charged Hollow Sphere and Point Charge
Replies
4
Views
1K
Induced charge on a conducting sphere sliced by a plane
Replies
2
Views
1K
Work done to insert a point charge 𝑞 at the center of a conducting sphere
Replies
12
Views
1K
I Electric Potential in circuit
Replies
3
Views
1K
I Solving Gauss' Law Problem: Zero E Field?
Replies
34
Views
3K

Hot Threads

Recent Insights

Back
Top