Inside a charged insulator, the electric field is 0, as charges cannot move freely in insulators. Outside the insulator, the electric field behaves as if all the charge is concentrated at the center of the insulator.
The electric field inside a charged insulator is zero, while the electric field outside a charged insulator is non-zero.
They are negatively charged particles. electrons are found inside an atom, outside its nucleus.
The electric field inside a uniformly charged sphere is zero.
A charged sphere with a cavity has the property that the electric field inside the cavity is zero. This means that any charge placed inside the cavity will not experience any electric force. The electric field outside the sphere behaves as if all the charge is concentrated at the center of the sphere.
Zero, because the electric field inside a charged hollow sphere is zero. This is due to the Gauss's law and symmetry of the charged hollow sphere, which results in no net electric field inside the sphere.
The electric field inside a charged insulator is zero, while the electric field outside a charged insulator is non-zero.
They are negatively charged particles. electrons are found inside an atom, outside its nucleus.
The electric field inside a uniformly charged sphere is zero.
A charged sphere with a cavity has the property that the electric field inside the cavity is zero. This means that any charge placed inside the cavity will not experience any electric force. The electric field outside the sphere behaves as if all the charge is concentrated at the center of the sphere.
Zero, because the electric field inside a charged hollow sphere is zero. This is due to the Gauss's law and symmetry of the charged hollow sphere, which results in no net electric field inside the sphere.
The electric field inside a charged sphere is uniform and directed radially towards the center of the sphere.
The electric field inside a cavity within a uniformly charged sphere is zero.
The electric potential inside a uniformly charged sphere is constant and the same at all points within the sphere.
Outside a charged spherical shell, the electric field behaves as if all the charge is concentrated at the center of the shell. This is known as Gauss's Law for a spherical surface, which states that the electric field at a distance r from the center of a charged spherical shell is equivalent to that of a point charge with the same total charge as the shell at the center. Therefore, the electric field outside a charged spherical shell decreases with the square of the distance from the center of the shell.
action potential
Inside a conductor, it's zero.
The electric field produced by a point charge is directly proportional to the charge and inversely proportional to the square of the distance from the charge. For a charged sphere, the electric field outside the sphere behaves as if all the charge is concentrated at the center, similar to a point charge. Inside the sphere, the electric field is zero.