A SPHERICAL conductor in electrostatic equilibrium has no further motion of charges within it. From this, it must imply that there is no net electric field in a conductor and this must necesssarily imply that qenclosed is zero.
This is fairly easy to see from Gauss's law:
(closed)∫E.dA = qenclosed/ε0
If E = 0, then ε0 = 0
Assuming inside the conductor is a negative point charge, then eventual distribution will result in negative charges on the inner surface of the conductor and positive charges on the outer surface of the conductor.
However,
1) It is hard for me to see this visually in a more complex case such as a coaxial cable.
2) Why is the electric field outside the SPHERICAL conductor ≠for a point outside of the conductor?
This is fairly easy to see from Gauss's law:
(closed)∫E.dA = qenclosed/ε0
If E = 0, then ε0 = 0
Assuming inside the conductor is a negative point charge, then eventual distribution will result in negative charges on the inner surface of the conductor and positive charges on the outer surface of the conductor.
However,
1) It is hard for me to see this visually in a more complex case such as a coaxial cable.
2) Why is the electric field outside the SPHERICAL conductor ≠for a point outside of the conductor?
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