The gravitational force is doubled.
As force of gravity is directly proportional to the mass as mass is doubled then force on it also gets doubled.
If one of the two masses doubles but the distance between them remains unchanged,then the magnitude of the gravitational force between them is also doubled.
When mass is doubled, gravitational attraction is doubled. There is a direct relationship.=========================Answer #2:Gravitational attraction always involves two objects, and the strength of thegravitational forces between them is proportional to the product of both masses.So . . .-- If one mass or the other is doubled, the forces are doubled.-- If both masses are doubled, the gravitational forces become 4 times as great.
If the mass of both of the objects is doubled, then the force of gravity between them is quadrupled; and so on. Since gravitational force is inversely proportional to the square of the separation distance between the two interacting objects, more separation distance will result in weaker gravitational forces.
The larger the mass, the stronger the gravitational force.
As force of gravity is directly proportional to the mass as mass is doubled then force on it also gets doubled.
The force is proportional to each of the masses. For example, if one of the masses is doubled, the gravitational force will also double.
Gravitational force is inversely proportional to the square of the distance. Therefore, double the distance = 1/22 = 1/4 the force.
If one of the two masses doubles but the distance between them remains unchanged,then the magnitude of the gravitational force between them is also doubled.
When mass is doubled, gravitational attraction is doubled. There is a direct relationship.=========================Answer #2:Gravitational attraction always involves two objects, and the strength of thegravitational forces between them is proportional to the product of both masses.So . . .-- If one mass or the other is doubled, the forces are doubled.-- If both masses are doubled, the gravitational forces become 4 times as great.
If the mass of both of the objects is doubled, then the force of gravity between them is quadrupled; and so on. Since gravitational force is inversely proportional to the square of the separation distance between the two interacting objects, more separation distance will result in weaker gravitational forces.
The larger the mass, the stronger the gravitational force.
The larger the mass, the stronger the gravitational force.
Gravitational force F = mass x g where g is the gravitational acceleration.
More mass --> more gravitational force Greater distance --> less gravitational force
Force = (m1)(m2)(G)/(r2) 16 = (m1)(m2)(G)/(r2) if we double each mass, and double the distance between them as well then the eq becomes force = (2m1)(2m2)(G)/(2r)2 force = 4(m1)(m2)(G)/4r2 force = (m1)(m2)(G)/(r2) = 16 N. The force remains unchanged.
Assuming by "the force acting on an object" you mean the cause of its acceleration, its acceleration will be doubled. If there is more than one force acting on it, the vector of the force will have to be analyzed by its effect on each of the other forces.