The electric field inside a uniformly charged sphere is zero.
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.
The electric field inside a charged sphere is uniform and directed radially towards the center of the sphere.
The voltage inside a uniformly charged sphere is directly related to the distribution of charge within the sphere. As the charge distribution becomes more uniform, the voltage inside the sphere becomes more evenly distributed. This means that the voltage is higher towards the center of the sphere where the charge is concentrated, and decreases towards the surface where the charge is spread out.
The distribution of the electric field inside a sphere is uniform, meaning it is the same at all points inside 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.
The electric field inside a charged sphere is uniform and directed radially towards the center of the sphere.
The voltage inside a uniformly charged sphere is directly related to the distribution of charge within the sphere. As the charge distribution becomes more uniform, the voltage inside the sphere becomes more evenly distributed. This means that the voltage is higher towards the center of the sphere where the charge is concentrated, and decreases towards the surface where the charge is spread out.
Inside a shell of charge, the electric field strength is zero, regardless of the thickness of the shell or the distribution of charge on it. This is due to the property of electrostatics known as Gauss's Law, which states that the electric field inside a closed surface enclosing a charge distribution is zero.
The distribution of the electric field inside a sphere is uniform, meaning it is the same at all points inside the sphere.
From Gauss's Law, Electric Field inside is 0, and it's electric flux is equal to Qenclosed/Eo, where Eo is the electric vacuum permittivity constant. Also, outside of the sphere, it could be treated as a point charge, where the point lies at the center of the shell and has a charge equal to the total charge of the shell.
The electric field inside a charged insulator is zero, while the electric field outside a charged insulator is non-zero.
The net electrostatic force acting on a charged particle located inside a shell of uniform charge is zero. This is because the electric field inside a uniformly charged shell is zero, meaning there are no forces acting on the charged particle from the shell itself.
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 hollow conductor is zero.
The charge distribution on a conducting shell affects the electric field inside the shell. If the charge is distributed evenly, the electric field inside the shell is zero. If the charge is not evenly distributed, there will be an electric field inside the shell.