-- They would appear larger to each other.
-- They would sound louder to each other.
-- They would smell stronger to each other.
-- They could play 'catch' more accurately.
-- Each of them would attract the other one with a stronger gravitational force.
-- If either or both of them is electrically charged, then the present attractive
or repulsive electrostatic force between them would be greater.
Gravitational forces between objects depend only on their masses and the distance between them. Velocity has no effect.
The gravitational force between two objects is directly proportional to the product of their masses and inversely proportional to the square of the distance between their centers.
The gravitational force is a force between any two masses (so, basically, any object). The force depends on the mass and on the distance. More mass --> more force; greater distance --> less force.
If there is more mass, there will be more gravitational attraction.
It can never escape it entirely. It can, however, travel fast enough that the increasing distance outweighs the effect of the decreasing gravity. On earth, this velocity is about seven miles per second.
the force will remain the p
They would be farther away.
Yes. At a greater distance, the gravitational attraction between two objects is less.
oscilation
-- the masses of both objects -- the distance between their centers
Mass and distance.
If the two objects are not interacting, then the rate of fall would be unaffected.
Gravitational forces between objects depend only on their masses and the distance between them. Velocity has no effect.
If the objects are not tied together, and if the gravitational forces between them are negligible in their current environment, then the distance between them has no effect whatsoever on their motion.
effect of Gravity varies according to the masses of the two objects, and the distance between them
This is false. The answer is that mass and distance affect the gravitational attraction between objects. Air resistance has no effect on this.
The gravitational force between two objects is directly proportional to the product of their masses and inversely proportional to the square of the distance between their centers.