Mass of the objects, and distance between them
(And they don't have to be in space. It can just as well be the gravitational force
between the lint in your pocket and a grain of sand on the beach in South Africa.
The same formula accurately calculates the magnitude of that force.)
Mass and distance affect the force of gravity between objects. The way these two variables affect the force is that gravity is directly proportional to mass. Double the mass and you double the force of gravity generated by a given object. Gravity is inversely proportional to the square of the distance between objects. If you double the distance between objects, only one quarter the gravity will be present. Halve the distance and four times the gravitational force will appear.
A planet's size and mass determines its gravitational pull. Gravity is the force that keeps planets in orbit around the Sun, and what keeps us rooted to the planet.
The gravitational force between two objects is directly proportional to the mass of each object, and inversely proportional to the square of the distance between them.
-- the masses of both objects
-- the distance between their centers of mass
Mass and the distance between the two masses
The two factors are the amount of mass an object has and the distance between the two objects.
The mass of an object effects the gravitational pull. The greater the mass, the greater the gravitational pull.
The masses involved, and the distance. More mass means more gravitational force. More distance means less force (inverse-square relation).
the mass of the attracted bodies, and the distance between them
Gravity is the attraction between two or more bodies. It is propotional to their mass and inversely proportional to their distance.
mass and distance form an inverse relationship when related to gravity. The larger the mass(es) the greater the gravitational pull. The closer the distance, the greater the gravitational pull.
Mass and distance. The force decreases with the square of the distance, so mass has a lesser effect on the equation.
The mutual gravitational forces between the Moon and the Earth are strongest when the distance between the two bodies is smallest. Just like the mutual gravitational forces between any other two bodies.
Not necessarily, gravitational pull is dependant upon the mass of an object. A smaller object can have more mass than a bigger object (An extremely dense 1x1x1 cube has more gravitational pull than a less dense 3x3x3 cube that has less mass). Size has absolutely NOTHING to do with gravitational pull.
The two factors related to gravitational pull are (total) mass and distance.
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.
Mass & distance.
The masses of the two objects and the distance between the two objects affect the gravitational force between them.
gravity and its orbit
The mass of each object, and the distance between them.
gravity and its orbit
gravity and its orbit
Two primary things:The masses of the two objects in question, andThe distance between them. Your answer would be 5.00e13
Gravity is the attraction between two or more bodies. It is propotional to their mass and inversely proportional to their distance.
Two factors affect the gravitational attraction between objects: mass and distance.