The gravitational attraction would b 9 times weaker because gravity is dependent on the inverse square of the distance.
If there is more mass, there will be more gravitational attraction.
If the distance between the star and planet were 3 times greater, the gravitational attraction between them would be inversely proportional to the square of the new distance. This means the gravitational force would be 1/9th of what it was originally. Gravity follows an inverse square law, so as the distance increases, the gravitational force decreases rapidly.
The gravitational force between two planets decreases with the square of the distance between them, according to Newton's law of universal gravitation. If the distance between the two planets is increased to three times their original distance, the gravitational force becomes one-ninth of what it was at the original distance. This means that as the distance increases, the gravitational attraction between the planets weakens significantly.
If the distance between the star and planet were 3 times as great, their gravitational attraction for each other would decrease by a factor of 1/9 (inverse square law). This means that the force of gravity between them would be 1/9 of what it was originally at the closer distance.
Mass and distance. The force decreases with the square of the distance, so mass has a lesser effect on the equation.
Yes, the distance between objects does affect the gravitational attraction between them. According to Newton's law of universal gravitation, the force of gravity decreases as the distance between two objects increases. This means that objects that are closer together will experience a stronger gravitational force than objects that are farther apart.
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.
If there is more mass, there will be more gravitational attraction.
This is false. The answer is that mass and distance affect the gravitational attraction between objects. Air resistance has no effect on this.
the force will remain the p
If the distance between the star and planet were 3 times greater, the gravitational attraction between them would be inversely proportional to the square of the new distance. This means the gravitational force would be 1/9th of what it was originally. Gravity follows an inverse square law, so as the distance increases, the gravitational force decreases rapidly.
As you move two objects away from each other their gravitational attraction gets weaker. Kind of like the bluetooth on phones :D
If the distance between the star and planet were 3 times as great, their gravitational attraction for each other would decrease by a factor of 1/9 (inverse square law). This means that the force of gravity between them would be 1/9 of what it was originally at the closer distance.
Mass and distance. The force decreases with the square of the distance, so mass has a lesser effect on the equation.
Massive means there is a lot of mass - and gravitational attraction depends on the amount of mass. The amount of gravitational attraction also depends on the distance - i.e., the effect will be less at larger distances. The gravitational attraction between galaxies is strong enough to make galaxies in a galaxy cluster stay together - for example, in our Local Group.
The separation distance is the independent variable in this scenario. By changing the separation distance between two objects, you can observe its effect on the force of attraction between them.
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.