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What must be the charge on each of two 100 kg spherical masses in order for the electrical force to be equal to the 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.
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What is the difference between electeical forces and gravitational forces?
-- Electrical force only cares about the charge on two objects, and ignores their mass. Gravitational force only cares about the mass of two objects, and ignores their charge. -- Electrical force can be attractive or repulsive. Gravitational force can only be attractive.
What is the gravitational force between 14 kg spherical masses that are 6 meters apart?
The gravitational force between two masses can be calculated using the formula: ( F = \frac{{G \cdot m_1 \cdot m_2}}{{r^2}} ), where ( G ) is the gravitational constant, ( m_1 ) and ( m_2 ) are the masses, and ( r ) is the distance between them. Substituting the given values, the gravitational force between two 14 kg spherical masses that are 6 meters apart can be calculated.
What would have the greatest gravitational attraction between the two masses?
The gravitational attraction between two masses depends on their masses and the distance between them. If the masses are large and close together, they would have the greatest gravitational attraction.
Rank the pairs of masses in order of increasing magnitude of gravitational force betweenthe masses?
The gravitational force between two masses is directly proportional to the product of the masses and inversely proportional to the square of the distance between them. So, to rank the pairs of masses in increasing magnitude of gravitational force, compare the products of masses for each pair. The pair with the smallest product of masses will have the weakest gravitational force, while the pair with the largest product of masses will have the strongest gravitational force.
Electrical and gravitational forces follow similar equations with one main difference?
Both electrical and gravitational forces follow an inverse square law, where the force decreases with the square of the distance between the objects. However, electrical forces can be attractive or repulsive depending on the charges of the objects involved, while gravitational forces are always attractive and only dependent on the masses of the objects.
What is the difference between electeical forces and gravitational forces?
-- Electrical force only cares about the charge on two objects, and ignores their mass. Gravitational force only cares about the mass of two objects, and ignores their charge. -- Electrical force can be attractive or repulsive. Gravitational force can only be attractive.
Difference between electric forces and gravitational forces is that electrical forces include?
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.
What is the gravitational force between 14 kg spherical masses that are 6 meters apart?
The gravitational force between two masses can be calculated using the formula: ( F = \frac{{G \cdot m_1 \cdot m_2}}{{r^2}} ), where ( G ) is the gravitational constant, ( m_1 ) and ( m_2 ) are the masses, and ( r ) is the distance between them. Substituting the given values, the gravitational force between two 14 kg spherical masses that are 6 meters apart can be calculated.
How are gravitational field and an electrical field similar?
The electrical field force acts between two charges, in the same way that the gravitational field force acts between two masses.
What is caused by the rotation and movement of energy of the sun and reach far out into space?
As far as I know, the only type of energy caused by the movement of masses - more accurately, the acceleration of masses - is gravitational waves. However, the roation of an object with spherical symmetry won't emit gravitational waves.
Is gravitational force is charge independent?
Yes. Gravitational force is proportional to the mass of the two objects and inversely proportional to the square of the distance between them. Charge does not enter into the picture.
What makes gravitational forces between two masses can you reproduce gravity?
The only thing that makes gravitational forces is mass. Any massive object (meaning any object that has mass, not an object of great mass) produces a gravitational field. The Calvendish Experiment that first measured the Gravitational constant employed two large spherical masses, probably bowling balls but but he was too proud to admit that such was what he used.
How is lightning created in the air and causes an electrical charge?
Lightening is created by the immense masses of different air pressures colliding and creating friction. The electrical charge is obvious from the friction.
What is Mass and Charge?
Mass of a body is a positive quantity. The gravitational force between two masses is always attractive. Electric charge can be positive or negative or zero.
What would have the greatest gravitational attraction between the two masses?
The gravitational attraction between two masses depends on their masses and the distance between them. If the masses are large and close together, they would have the greatest gravitational attraction.
Rank the pairs of masses in order of increasing magnitude of gravitational force betweenthe masses?
The gravitational force between two masses is directly proportional to the product of the masses and inversely proportional to the square of the distance between them. So, to rank the pairs of masses in increasing magnitude of gravitational force, compare the products of masses for each pair. The pair with the smallest product of masses will have the weakest gravitational force, while the pair with the largest product of masses will have the strongest gravitational force.
How can the subatomic particles be distinguished?
They have different masses, electrical charge, dimensions, life time, spin etc.
