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True. The strength of an electrical field follows an inverse square law.
An electric field gets stronger the closer you get to a charge exerting that field. Distance and field strength are inversely proportional. When distance is increased, field strength decreases. The opposite is true as well. Additionally, field strength varies as the inverse square of the distance between the charge and the observer. Double the distance and you will find that there is 1/22 or 1/4th the electric field strength as there was at the start of your experiment.
The strength of the electric field approaches zero
Magnetic field lines are stronger when closer together.
Electromagnetic and electrostatic fields are present. The strength of each field is dependent upon the components in the electrical circuit.
True. The strength of an electrical field follows an inverse square law.
An electric field gets stronger the closer you get to a charge exerting that field. Distance and field strength are inversely proportional. When distance is increased, field strength decreases. The opposite is true as well. Additionally, field strength varies as the inverse square of the distance between the charge and the observer. Double the distance and you will find that there is 1/22 or 1/4th the electric field strength as there was at the start of your experiment.
the same, just closer.
The closer the lines the stronger the magnetic field.
The strength of the electric field approaches zero
No. The strength of the electric field remains unchanged regardless of your proximity. However, the effects of the electric field on you are more pronounced as you move closer to it.
The answer would depend on how it was made to orbit and the strength of the electrical field.
the electrical potential is also increased;electricity does not travel through wire but around the outside,which is why transmission lines are bare
A measure of ability of a material tro resist the formation of electrical field within it equal to ratio between electrical flux density and electrical field strength generated by an electrical charge on the material. It is defined by permittivity.
It induces an electrical current
The closer the lines of force are together, the stronger the magnetic field it represents.
it will decrease as radius increase keeping mass same