The equation for gravitational force is F=(GM1M2)/R2
Where R is the distance between the 2 objects, this is an inverse square law. So if you double the distance between the 2 objects the force gets 4 times smaller.
Considering Einstein's theory of space-time, each object within space emits a gravitational force. Usually, this force is so small it is, even at the atomic scale, impossible to see. However, when enough mass is in a certain location in a given time a sort of 'depression' within the black slate of space begins to form, causing objects to pull towards the object with varying force, depending on the mass of the celestial object in question.
To answer your question, gravitational force lessens as you leave the 'depression' in space-time, as would you climb up if you were, in metaphor, climbing up from a valley to a hill. This would cause two celestial bodies to lessen their pull towards each other as distance increased. It is unknown why or truly how, but it is very well known what and when.
As distance decreases, gravitational force increases.
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.
Decreasing the distance between two objects will increase the force of gravity. Gravity is proportional to the mass of the two objects and inversely proportional to the square of the distance between them.
I think what you're trying to get at is "How big does an object have to be to have gravity?" which is different from "gravitation". Gravitation is something that everything has, big or small. It is the attraction that all objects exert on one another. Gravity, on the other hand, is specifically the force that a massive object exerts on other objects.
Not materially. The voltage is determined by the composition of the electrodes and the medium in which they are placed.
Acids can destroy many objects by corrosion.
The masses of the two objects and the distance between the two objects affect the gravitational force between them.
Distance decreases the gravitational force, F=k/r2.
mass and distance
This is false. The answer is that mass and distance affect the gravitational attraction between objects. Air resistance has no effect on this.
Two primary things:The masses of the two objects in question, andThe distance between them. Your answer would be 5.00e13
There are two factors that affect the gravitational attraction between two objects. The mass of each object and the distance between their centers of mass are the factors that affect the attraction.
There are two factors that affect the gravitational attraction between two objects. The mass of each object and the distance between their centers of mass are the factors that affect the attraction.
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.
it decreases the gravitational force.
Yes. The gravitational force between objects always depends only on their masses and the distance between them.
Two factors affect the gravitational attraction between objects: mass and distance.
-- the product of their individual masses -- the distance between their centers The formula for the gravitational force is given by: force = GMm/r² where G is the gravitational constant, M and m are the masses of the two objects and r is the distance between their centres.