When can a charged sphere be treated as a point charge?

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Discussion Overview

The discussion centers around the conditions under which a charged sphere can be treated as a point charge, exploring the implications of charge distribution and symmetry in electric fields. The scope includes theoretical considerations and applications of Gauss's law in electrostatics.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • Some participants suggest that a charged sphere can be treated as a point charge when the charge distribution is spherically symmetric, leading to an electric field equivalent to that of a point charge at the center.
  • Others argue that this treatment holds true specifically for uniformly distributed charges over the sphere's volume or surface.
  • A participant notes that the isolation of the sphere from other charges is crucial; if external charges are present, they can induce non-symmetric surface charges, complicating the point charge approximation.
  • It is proposed that if the radius of the sphere is very small compared to the characteristic lengths of the system, it may still be treated as a point charge due to induced charges approximating spherical symmetry.
  • Some participants discuss the application of Gauss's law, stating that it can be used to model the electric field as that of a point charge under certain conditions.
  • However, there is contention regarding the validity of using Gaussian surfaces when symmetry is lost, with some asserting that advanced methods must be employed in such cases.
  • Concerns are raised about the assumption that shifting the Gaussian surface can maintain the validity of the point charge model when external charges are involved.

Areas of Agreement / Disagreement

Participants express a mix of agreement and disagreement regarding the conditions for treating a charged sphere as a point charge. While some aspects, such as the importance of symmetry, are acknowledged, there is no consensus on the implications of external charges and the use of Gaussian surfaces in non-symmetric situations.

Contextual Notes

Limitations include the dependence on the definitions of symmetry and the conditions under which the Gaussian law applies. The discussion reflects various interpretations of how external influences affect the electric field and the validity of approximations.

annms
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Not much more to add to the title. I was just wondering, under what conditions can a charged sphere be treated as a point charge?
 
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The electric field outside a (uniformly) charged sphere is equal to the electric field that would have been created by a point charge with the same total charge.
 
annms said:
I was just wondering, under what conditions can a charged sphere be treated as a point charge?
When the charge distribution is spherically symmetric, the field outside the sphere is exactly that of a point charge at the center of the sphere. (Where the charge of the point charge equals the total charge of the sphere.)
 
So in cases when the charge is uniformly distributed over its volume or its surface, the sphere can be treated as a point charge?
 
yep. Doc Al's response is slightly more accurate than mine - as long as the charge distribution is symmetric, the electric field outside will be same as that created by a point charge.

So any symmetric distribution you can think of will have this remarkable property.

Edit: For clarity, symmetric just means that the charge distribution will only depend on the radius. (Well, that's probably not the technical meaning of symmetric, but that's what it means in this example).
 
Apply the Gauss law in Maxwell's equations. Integral form, ∫E·dA=Q/ε0, where Q is the charge bounded inside the close surface. For any spherical Gaussian surface, E4πr2=Q/ε0, and is exactly the same as coulomb's law for point charge.

This means you can apply to whatever the charge distribution, it can be modeled by a equivalent point charge.
 
"When can a charged sphere be treated as a point charge? "

This is only true if the sphere is isolated from everything else. If another charge, or another object held at some potential, is brought near the sphere, it will induce surface charges in the sphere that are not spherically symmetric, and therefore you can no longer treat it as a point charge. But if the radius of the sphere is very small compared to characteristic lengths of the system, then you can treat it as a point charge even if it is not isolated because the induced charges will be spherically symmetric as an approximation if the sphere is very small.
 
chrisbaird said:
"When can a charged sphere be treated as a point charge? "

This is only true if the sphere is isolated from everything else. If another charge, or another object held at some potential, is brought near the sphere, it will induce surface charges in the sphere that are not spherically symmetric, and therefore you can no longer treat it as a point charge. But if the radius of the sphere is very small compared to characteristic lengths of the system, then you can treat it as a point charge even if it is not isolated because the induced charges will be spherically symmetric as an approximation if the sphere is very small.

But it can still be viewed as an point charge by taking a new gaussian surface where the centre shifts to the new equivalent point charge and take a larger sphere. Everywhere outside the surface the model is still valid.

But when there is an external charge the field is again distorted. Actually the net field should be modeled by another equivalent charge and a even larger sphere as gaussian surface.
 
ZealScience said:
But it can still be viewed as an point charge by taking a new gaussian surface where the centre shifts to the new equivalent point charge and take a larger sphere. Everywhere outside the surface the model is still valid.

But when there is an external charge the field is again distorted. Actually the net field should be modeled by another equivalent charge and a even larger sphere as gaussian surface.

I think you are confused. The Guassian-surface trick only works if you have a constant field over the Gaussian surface which will only happens if the charge density if there is symmetry (a spherical Gaussian surface requires a spherically symmetric charge density, a cylindrical Guassian surface requires...,etc). As soon as the symmetry is lost, the Guassian-surface trick no longer works and you have to go to more advanced methods (method of images, Green functions, etc).
 
  • #10
ZealScience said:
But it can still be viewed as an point charge by taking a new gaussian surface where the centre shifts to the new equivalent point charge and take a larger sphere. Everywhere outside the surface the model is still valid.

But when there is an external charge the field is again distorted. Actually the net field should be modeled by another equivalent charge and a even larger sphere as gaussian surface.

No, no, no. Even if you shift the centre and use a larger gaussian sphere, the electric field at each point on that gaussian sphere would not be equal. (Because the distribution is no longer symmetric).
 

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