the gravitational force pulling them together is reduced.
The gravitational force becomes 4 times stronger than it was before the objects moved closer.
If the masses do not change, but the objects are moved farther apart, the gravitational force becomes weaker, due to the distance between the objects.
The intensity of the gravitational force is smaller.
" ... decreases." Gravitational force is inversely proportional to the square of the distance between the objects.
The gravitational force is INVERSELY proportional to the SQUARE of the distance; that means that if you change the distance by a factor of "n", the force will change by a factor of "n squared". In this case, 4 x 4 = 16; the force will INCREASE by a factor of 16.
the gravitational force pulling them together is reduced.
The gravitational force becomes 4 times stronger than it was before the objects moved closer.
The intensity of the gravitational force is smaller.
If the masses do not change, but the objects are moved farther apart, the gravitational force becomes weaker, due to the distance between the objects.
" ... decreases." Gravitational force is inversely proportional to the square of the distance between the objects.
The gravitational force between objects increases as the distance between objects decreases.
The gravitational force is INVERSELY proportional to the SQUARE of the distance; that means that if you change the distance by a factor of "n", the force will change by a factor of "n squared". In this case, 4 x 4 = 16; the force will INCREASE by a factor of 16.
Gravitational force = GM1M2/D2 The distance is squared and in the numerator
the force of gravity depends on the product of the masses of the objects divided by the square of the distance between the objects. example: if two objects are moved twice as far apart, the gravitational attraction between them will decrease by 2 times 2(a factor of 4)
One thing that could happen is that the force that acts between them decreases.
When objects get moved using muscles in the body
because it is due to the force's motion.