It decreases as the square of the distance.
The gravitational attraction between two objects increases as the mass of one or both objects increases. This is because gravitational force is directly proportional to the mass of the objects. Therefore, the more massive the objects are, the stronger the gravitational attraction between them.
The gravitational force between two objects increases as their masses increase. This is because gravitational force is directly proportional to the product of the masses of the two objects. As the masses increase, the force of attraction between them also increases.
As the orbital radius increases, the period of the orbit also increases. This is because the gravitational force weakens with distance and it takes longer for the object to complete a full orbit at larger distances from the center of mass.
It decreases[:
It increases.
As a rock gets closer to Earth, the force of gravity acting on it increases. This is because gravitational force is inversely proportional to the square of the distance between the two masses, according to Newton's law of universal gravitation. Therefore, as the distance decreases, the gravitational attraction grows stronger. However, for small distances relative to Earth's radius, this change is relatively small and often negligible in everyday scenarios.
Gravity force will be reduced by a factor of 4.
It decreases as the square of the distance.
Erosion increases due to the effective gravitational gradient.
At greater distances, the force of gravity becomes less.
If the distance between them is decreasing, then the mutual gravitational attraction is increasing. They don't necessarily have to be accelerating. Just moving steadily would do it, as long as the separation distance is decreasing.
The value of the Gravitational Potential Energy decreases as the distance (r) between the objects increases. This is because the gravitational force weakens with distance, resulting in a decrease in potential energy as the objects move farther apart.