A positively charged solid conducting sphere is contained within

How do you find the potential of a solid conducting sphere?

A solid conducting sphere of radius R has a total charge q. Find the potential everywhere, both outside and inside the sphere. From the previous analysis, you know that the charge will be distributed on the surface of the conducting sphere. Exploiting the spherical symmetry with Gauss’s Law, for , At r = R, just sub. r = R into the above equations.

What happens if a sphere is positively or negatively charged?

Regardless of whether the sphere is positively or negatively charged, all the excess charge is on the surface. This follows from Gauss's law. So, if the sphere is negatively charged, all the excess electrons lie on the surface of the sphere. If it is positively charged, then the "missing" electrons are missing at the surface.

How does a conductive sphere work?

A cool conductive (metal) sphere is placed in vacuum. The sphere is initially neutrally charged and is then given a net-positive charge followed by a net-negative charge. Between these changes in charge, time is allowed to allow the system to come to equilibrium.

How do you find the field of a charge outside a sphere?

This expression is the same as that for a point charge; outside the charged sphere, its field is the same as though the entire charge were concentrated at its center. Just outside the surface of the sphere, where r = R, E = 1 4πϵ0 q R2 E = 1 4 π ϵ 0 q R 2 (at the surface of a charged conducting sphere)

What is a positively charged metal sphere?

One more thing: Most of the time in the real world, when we talk about a "positively charged metal sphere" or something like that, we mean a sphere which has had some electrons removed, so that the number of protons remaining is greater than the number of electrons, thus giving the sphere a net positive charge.

What is the electric field inside a spherical conductor?

The electric field inside the conductor is therefore zero. We already knew that E = 0 inside a solid conductor (whether spherical or not) when the charges are at rest. Figure 1 shows E as a function of the distance r from the center of the sphere.