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Gravitational force? Mass 1 times mass 2 divided by the square or the distance between them?
If the objects are the same distance apart (center to center), then the gravitational force between two less massive objects will be less than the gravitational force between two more massive objects.
Answer The Universal Law of Gravitation states the gravitational force between any two objects of mass can be calculated with the equation F=G*(m_1*m_2)/r^2. As a result, increasing the mass of one or both objects increases the gravitational force. Increasing the distance between the two objects decreases the gravitational force. Notice the distance between them is squared so if you keep the masses the same and double the distance between them the gravitational force will decrease by four times.
Yes. At a greater distance, the gravitational attraction between two objects is less.
The gravitational force is proportional to the mass of the objects: Between two 50 kg objects it is ten times stronger than between a 5 and a 50 kg object. The gravitational force is also dependent on the distance between the two masses. The force is inversely proportional to the square of the distance. Therefore, the gravitational force between two 50Kg objects can be less than a 50Kg and a 5Kg object if the distance between the two 50Kg objects is greater than the distance between the 5Kg and 50Kg objects. See link for the equation to calculate the gravitational force.
Gravitational force? Mass 1 times mass 2 divided by the square or the distance between them?
If the objects are the same distance apart (center to center), then the gravitational force between two less massive objects will be less than the gravitational force between two more massive objects.
Answer The Universal Law of Gravitation states the gravitational force between any two objects of mass can be calculated with the equation F=G*(m_1*m_2)/r^2. As a result, increasing the mass of one or both objects increases the gravitational force. Increasing the distance between the two objects decreases the gravitational force. Notice the distance between them is squared so if you keep the masses the same and double the distance between them the gravitational force will decrease by four times.
Yes. At a greater distance, the gravitational attraction between two objects is less.
The gravitational force is proportional to the mass of the objects: Between two 50 kg objects it is ten times stronger than between a 5 and a 50 kg object. The gravitational force is also dependent on the distance between the two masses. The force is inversely proportional to the square of the distance. Therefore, the gravitational force between two 50Kg objects can be less than a 50Kg and a 5Kg object if the distance between the two 50Kg objects is greater than the distance between the 5Kg and 50Kg objects. See link for the equation to calculate the gravitational force.
The masses of the two objects and the distance between the two objects affect the gravitational force between them.
The objects weight is a measure of that force.
When you don't have gravitational interaction between objects.
A physical quantity is a number of object(s) that are tangible objects. A number doesn't have to represent any specific quantity of items, but rather just a quantity in an equation. Phsyical quantity: 5 chairs, 2 apples
Mass
The gravitational force between two masses is given by the equation: F = G * (m1 * m2) / d^2 where F is the force, G is the gravitational constant, m1 and m2 are the masses of the two objects, and d is the distance between the two objects. If the distance between the two masses is quadrupled, the distance between the two objects (d) in the equation will be 4 times greater, so the denominator of the equation will be 4^2 = 16 times greater. To see the effect of this change on the gravitational force, we'll divide the new value by the original value: (1/(4^2)) = 1/16 So, when the distance between two masses is quadrupled, the gravitational force between them is 1/16 of its original value.
The magnituide of the gravitational force between two objects will increase if -- the mass of one or both objects increases OR -- the distance between their centers-of-mass decreases.