If by "better" you mean "stronger", the greater masses will cause a stronger gravitational force.
At the same distance, objects with more mass will have a greater gravitational attraction.
Assuming the distance between the two objects does not increase then the gravitational force will become 4 times as great.
Yes. At a greater distance, the gravitational attraction between two objects is less.
Assuming you mean the force of gravity. As the distance increases, the force of gravity is reduced exponentially. Double the distance between two bodies, the gravitational force is reduced four times.
If you increase the mass, you increase the gravitational force proportionally. If you increase the distance between two masses, you decrease the gravitational force between them by and amount proportional to the square of the distance.
At the same distance, objects with more mass will have a greater gravitational attraction.
Assuming the distance between the two objects does not increase then the gravitational force will become 4 times as great.
Assuming that both have mass, then in order to completely eliminate the gravitational forces between them, an infinite distance between their centers is required.
Assuming you mean the force of gravity. As the distance increases, the force of gravity is reduced exponentially. Double the distance between two bodies, the gravitational force is reduced four times.
Yes. At a greater distance, the gravitational attraction between two objects is less.
The gravitational force between the Earth and sun certainly depends on the distance between the Earth and sun. But the gravitational force between, for example, the Earth and me does not.
the gravitational force between them decreases.
Distance decreases the gravitational force, F=k/r2.
Well, the equation for calculating the gravitational force between two objects is Fg= GMm/r2. So, G is the universal gravitation constant. Uppercase M is the larger mass and lowercase m is the smaller mass of the two. R is the distance between the centre of the two masses assuming they are spherical masses. So, to answer your question, the mass and distance directly affects the gravitational attraction of two objects. The greater the mass and the less distance, the greater the gravitational attraction. When distance is increased between two objects, the gravitational attraction decreases. This goes the same for mass.
If you increase the mass, you increase the gravitational force proportionally. If you increase the distance between two masses, you decrease the gravitational force between them by and amount proportional to the square of the distance.
The gravitational force that one object exerts on another will decrease in magnitude. In the formula for gravitational force, the force is inversely proportional to the square of distance. This means that reducing the distance between the objects will increase the magnitude of gravitational force.
since gravitational force is inversely propostional to the sq. Root of distance between them. When distance increases the gravitational force decreasses and it is vice versa.