If the distance between two masses is tripled, then the gravitational force between them
becomes (1/32) = 1/9th as great as it started out.
mass and distance
The gravitational attraction would b 9 times weaker because gravity is dependent on the inverse square of the distance.
The greater distance between two objects affects the gravity by making it weak.
The gravitational attraction would be 9 times weaker, this is because gravity is dependent on the inverse square of the distance.
If they are farther apart, there is less gravitational pull. Opposite if they are closer together.
Yes. At a greater distance, the gravitational attraction between two objects is less.
The force of gravitational attraction is inversely proportional to the square of the distance between the centers of mass of the objects. For example, if the distance increases by a factor of two, the attraction is reduced by a factor of four.
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.
There are two factors that affect the gravitational attraction between two objects. The mass of each object and the distance between their centers of mass are the factors that affect the attraction.
mass and distance
There are two factors that affect the gravitational attraction between two objects. The mass of each object and the distance between their centers of mass are the factors that affect the attraction.
The gravitational attraction would b 9 times weaker because gravity is dependent on the inverse square of the distance.
and The Distance Between Them.
Gravitational force is dependent on mass and distance.
This is false. The answer is that mass and distance affect the gravitational attraction between objects. Air resistance has no effect on this.
The masses of the different objects The distance between them
Decreasing the distance between two objects will increase the force of gravity. Gravity is proportional to the mass of the two objects and inversely proportional to the square of the distance between them.