In case of electric force there are both repulsive and attractive. But in case of gravitational force, only attractive force. Electrical force between electric charges. Gravitational force between masses. In electric force we use a constant known as permittivity of the medium. But in gravitational force a universal constant known as Gravitational constant is used. Electrical force is very much greater than gravitational force.
The strong nuclear force is a fundamental force that binds protons and neutrons within an atomic nucleus. It is charge-independent because it acts the same way on protons (positively charged) and neutrons (no charge), overcoming the electromagnetic repulsion between protons. This force is responsible for the stability of atomic nuclei.
Yes, the thrust on the rocket remains constant in the absence of gravitational force. Thrust is the force pushing the rocket forward, generated by the propulsion system. It is independent of gravitational force.
The gravitational force of black hole is unlimited.
Gravitational force is the natural phenomenon that causes objects with mass to be attracted to one another. For example, the gravitational force between the Earth and the Moon is what keeps the Moon in orbit around the Earth.
F=mg where g is the gravitational constant, and the independent variable in force calculations
Electric force depends on the charge of the objects involved, analogous to mass in gravitational force. The greater the charge of the objects, the stronger the electric force between them.
The mass of an object does not change when the gravitational force changes. Mass is a measure of the amount of matter in an object and is independent of the gravitational force acting on it.
No, mass remains constant regardless of changes in gravitational force. Mass is a measure of the amount of matter in an object and is independent of gravitational force, whereas weight, which is the force acting on an object due to gravity, can change with variations in gravitational force.
If the gravitational force is equal to the electrostatic force, the direction of the charge will depend on the relative signs of the charges. If the charges are of opposite sign, the direction will be attractive (towards each other), and if the charges are of the same sign, the direction will be repulsive (away from each other).
Coulomb's force is the electrostatic force between charged particles, while gravitational force is the force of attraction between masses due to gravity. Coulomb's force depends on the amount of charge and distance between charges, while gravitational force depends on the masses and distance between objects. Coulomb's force is much stronger than gravitational force for everyday objects.
In case of electric force there are both repulsive and attractive. But in case of gravitational force, only attractive force. Electrical force between electric charges. Gravitational force between masses. In electric force we use a constant known as permittivity of the medium. But in gravitational force a universal constant known as Gravitational constant is used. Electrical force is very much greater than gravitational force.
The electrical force between the two masses is equal to the gravitational force when the magnitude of the electrical force, given by Coulomb's law, is equal to the magnitude of the gravitational force, given by Newton's law of universal gravitation. By setting these equal and solving for charge, you can find that the charges on the two masses must be around 1.45 x 10^17 C each.
Yes, electrostatic force is charge dependent and independent of mass. The force between two charged objects is determined by the magnitude of the charges and the distance between them, not by the mass of the objects.
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The strong nuclear force is a fundamental force that binds protons and neutrons within an atomic nucleus. It is charge-independent because it acts the same way on protons (positively charged) and neutrons (no charge), overcoming the electromagnetic repulsion between protons. This force is responsible for the stability of atomic nuclei.
The electric force is stronger than the gravitational force because electric charges can be positive or negative, allowing for attractive and repulsive interactions, while gravity is always attractive. Additionally, the strength of the electric force is determined by the charge of the particles involved, which can be much larger than the masses involved in gravitational interactions.