Electric field lines extend around a charged object. These lines represent the direction in which a positive test charge would move if placed in the vicinity of the charged object. The electric field is strongest closer to the charged object and gets weaker as you move further away.
The strength of an electric field decreases with distance. As you move farther away from a charged object, the electric field intensity becomes weaker. This relationship follows an inverse square law, meaning that the electric field strength is inversely proportional to the square of the distance from the charged object.
Yes, the strength of an electric field from a charged particle is stronger closer to the particle and weaker as you move further away. The electric field decreases with distance according to the inverse square law, which means it decreases as the square of the distance from the charged particle.
No, an object with a static charge can attract both charged and neutral objects. This is because the static charge can induce a temporary charge separation in neutral objects, causing an attraction between them.
Electric force can act at a distance, but is stronger when objects are closer. the electric force is larger the closer the two objects are The electric force varies with the distance between the charges. The closer they are, the stronger the force. The farther apart they are, the weaker the force.
Electric field lines extend around a charged object. These lines represent the direction in which a positive test charge would move if placed in the vicinity of the charged object. The electric field is strongest closer to the charged object and gets weaker as you move further away.
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 strength of an electric field decreases with distance. As you move farther away from a charged object, the electric field intensity becomes weaker. This relationship follows an inverse square law, meaning that the electric field strength is inversely proportional to the square of the distance from the charged object.
Yes, the strength of an electric field from a charged particle is stronger closer to the particle and weaker as you move further away. The electric field decreases with distance according to the inverse square law, which means it decreases as the square of the distance from the charged particle.
weaker as square of distance
No, an object with a static charge can attract both charged and neutral objects. This is because the static charge can induce a temporary charge separation in neutral objects, causing an attraction between them.
An object have greater gravitational pull closer from earth. As we get farther from earth, the gravitational pull becomes weaker. That is why objects sufficiently away from the earth do not fall on it.
Electric force can act at a distance, but is stronger when objects are closer. the electric force is larger the closer the two objects are The electric force varies with the distance between the charges. The closer they are, the stronger the force. The farther apart they are, the weaker the force.
No, the strength of the electric field of a charged particle becomes weaker as the distance from the particle increases. The electric field strength follows an inverse square law relationship with distance, meaning it decreases as the distance from the charged particle increases.
No, the strength of the electric field of a charged particle decreases as the distance from the particle increases according to the inverse-square law. Therefore, the farther you are from a charged particle, the weaker the electric field strength.
The electric force between two charged objects decreases as they move apart. This decrease in force is inversely proportional to the square of the distance between them according to Coulomb's Law.
The attraction or repulsion between electric charges is stronger when they are closer together and weaker when they are far apart. This is described by Coulomb's law, which states that the force between two charges is directly proportional to the product of the charges and inversely proportional to the square of the distance between them.