If both masses double, then the force increases by (2 x 2) = 4 times.
If the distance doubles, then the force decreases to 1/22 = 1/4
So if the distance and both masses all double, then the magnitude of the
gravitational force is unchanged.
The force is reduced by a factor of 16. (Inverse Square Law)
Fg = (G*m1*m2)/(r^2)
An increase in mass of either body by a factor of ten will increase the force of gravity between the two bodies to the same degree
If both objects mass increases by a factor of 10, gravity force will increase by a factor of 100.
(Masses remaining the same) the force would be ( original force * ( 1 / 42 ) )
= 1 / 16 of the original force
Mass, not density, and the closeness of objects, affects an object's gravitational pull. Density is not dependent on an object's size, but mass is. The more massive an object, and/or the closer an object is to another, the greater its gravitational pull.
The gravitational force between two objects depends on the product of their masses.That means (mass #1) times (mass #2).If Mass-#1 is you, then the gravitational force between you and another object depends on the massof the other object.Since the earth has much more mass than the moon, the gravitational force between you and the earth islarger than the gravitational force between you and the moon.(The force also depends on the distance between the two objects. But you should already begetting the idea, without going into the other details.)
Which object exerts more gravitational force, object A with a mass of 25 grams and a density of 2 g/cm3 or object B with a mass of 55 grams and a density of 0.5 g/cm3? Gravitational force is dependant on the mass and the mass alone. Object B mass 55 g will exert a force on say a mass of 1g at a say 1 meter over twice that of object A . In the gravitational field of earth one would weigh 55g and the other 25g As the gravitational force between two masses is is G X (M1 X M2)/R2 where R is the distance between them there is will be an attractive force between the two objects that that acts on both objects. In the absence of any other forces they will move towards each, g the 25 g object accelerating more quickly.
The force of gravity is proportional to the mass of an object and inversely proportional to the square of the distance between the objects. Venus is nearer the Sun than Earth.
The farther away the objects are the weaker the pull of gravity is. Also, the more massive an object is, the stronger the gravitional pull is.
If you double the mass of the first object, double the mass of the second object, and double the distance between them, the gravitational forces between them are exactly the same as before all the doubling began.
The gravitational force is proportional to each of this masses. Thus, for example, if one of the masses is double, the force will also double.
Mass
It doubles. F=(Gm1m2)/r2 G=gravitational constant, m1= mass of one object, m2= mass of other object, r= distance between them, F=gravitational force (It also begins to exert double the force on other objects nearby.)
mass of the objects and the distance between the objects. gravitational force can be found using: , where G is gravitational constant, m1 is the mass of object 1 (in kg) m2 is the mass of object 2 (in kg) r is the distance between the objects (in meters)
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 depends on the masses of both objects and the distance between them. The formula is Gravitational Force = 6.67428 * 10^-11 * Mass of First Object * Mass of Second Object / Distance^2.
The mass of the objects and the distance between them.
As mass increases, so does the gravitational pull from the object.
The larger the mass of either object, the greater the gravitational force.
Move the objects closer together.
It is directly proportional to the product of the masses and inversely proportional to the square of the distance between the centres of mass of the objects.