If the charge is uniformly distributed over the shell,
then the electric field is zero everywhere inside.
In a conducting sheet, the electric field is zero inside the material but can exist on the surface due to excess charge redistribution. In a non-conducting sheet, the electric field can exist both inside the material and on the surface, depending on the charge distribution.
yes it can We have Epsilon equals charge by area imagine a photographic enlargement of the charge inside which this point charge exists then you can calculate B(Mag. Field intensity) We have E=Int.(B.dA) Was ur doubt clarified?
electric field inside the conducting sphere is ZER0..! because their are equivalent charges all around the sphere which makes the net force zero hence we can say that the electric field is also zero.!
Factors affecting the magnetic field strength of a solenoid are: - length of the solenoid - diameter of the solenoid - current through the coil around the solenoid - number of turns of the coil of current around the solenoid, usually turns of wire - material in the core
A magnetic field is created by moving electric charges, such as electrons. The strength of a magnetic field is affected by the distance from the source, the amount of current flowing, and the material through which the magnetic field is passing. Increasing the current or using materials with higher magnetic permeability will result in a stronger magnetic field.
The flux through a cube with a charge inside is the total electric field passing through the cube's surface. It is a measure of the electric field strength and direction at the surface of the cube due to the charge inside.
The distribution of the electric field inside a sphere with non-uniform charge density varies depending on the specific distribution of charges within the sphere. The electric field strength at any point inside the sphere can be calculated using the principles of Gauss's Law and the superposition principle. The field strength will be stronger in regions with higher charge density and weaker in regions with lower charge density.
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.
The electric field inside a sphere of uniform charge density is zero.
Yes, the charges inside a conductor will rearrange when an external charge is placed near or on the surface of the conductor, resulting in an induced electric field inside the conductor. This induced electric field will influence the external charge's behavior without the need for direct contact between the charges.
They are negatively charged particles. electrons are found inside an atom, outside its nucleus.
Electrons
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.
The presence of a charge inside a conductor affects the distribution of electric potential by causing the charges to redistribute themselves in such a way that the electric potential is the same throughout the material. This is known as electrostatic equilibrium.
The electric potential inside a parallel-plate capacitor is directly proportional to the charge on the plates and inversely proportional to the separation distance between the plates. This means that as the charge on the plates increases, the electric potential also increases, and as the separation distance between the plates decreases, the electric potential increases.
1. Electric field lines of force originate from the positive charge and terminate at the negative charge. 2. Electric field lines of force can never intersect each other. 3. Electric field lines of force are not present inside the conductor, it is because electric field inside the conductor is always zero. 4. Electric field lines of force are always perpendicular to the surface of conductor. 5. Curved electric field lines are always non-uniform in nature.
The electric field inside an infinitely long cylindrical conductor with radius r and uniform surface charge density is zero.