The strength of the mutual forces of gravity that attract two objects toward each
other is called the "weight" of each object in the presence of the other one.
The strength of the mutual gravitational forces that attract you and the earth
toward each other is called your weight on the earth. Nobody cares about the
earth's weight on you, but it's exactly the same number.
it will affect its weight as weight of an object is the gravitational pull acting on it...
It will change your weight.
Weight
weight
Any two objects experience a pair of gravitational forces, one force on each object, that draw them together. Both forces are equal, and their strength depends on the masses of both objects, and on the distance between the objects. If you're one of the objects, then you call the force your "weight" on the Earth. It's important to realize that the Earth feels the same force toward you, and that force is the Earth's weight on you.
The two factors that affect the force of gravity between two objects are mass and distance. The force of gravity is directly proportional to the product of the masses of the two objects, and inversely proportional to the square of the distance separating the two objects.
Force of gravity also increases proportionally.
Gravity attracts all mass, period. More massive objects have higher gravity, but even low masses will attract.
The ratio of the force of gravity which these objects exert on some other objects are equal to the ratio of the masses. Otherwise, if you want to know the difference in absolute terms (subtracting one force minus the other), you would also have to know the mass of the other object on which they act, as well as the distance. Regarding only the force of gravity ON these two objects . . . -- Assume both objects are in the same place, and that place is on or near the Earth's surface. -- The force of gravity on the more-massive object is (Mbig G) = (23.5)(9.8) -- The force of gravity on the less-massive object is (Mlittle G) = (14.7)(9.8) -- The difference between the two forces is (23.5 - 14.7)(9.8) = 86.3 newtons (about 19.4 pounds).
Yes, though the force of gravity extends infinitely, it does attract far objects less than near objects.
Any two objects experience a pair of gravitational forces, one force on each object, that draw them together. Both forces are equal, and their strength depends on the masses of both objects, and on the distance between the objects. If you're one of the objects, then you call the force your "weight" on the Earth. It's important to realize that the Earth feels the same force toward you, and that force is the Earth's weight on you.
The force that pulls an object toward earth also pulls the earth toward the object.The two forces are equal. Together, we refer to them as the force of gravity.Isaac Newton developed this concept.Gravity. The Earth has more mass than the object, it pulls it towards its' center.
The two factors that affect the force of gravity between two objects are mass and distance. The force of gravity is directly proportional to the product of the masses of the two objects, and inversely proportional to the square of the distance separating the two objects.
The farther away the objects are the weaker the pull of gravity is. Also, the more massive an object is, the stronger the gravitional pull is.
Force of gravity also increases proportionally.
Gravity attracts all mass, period. More massive objects have higher gravity, but even low masses will attract.
The ratio of the force of gravity which these objects exert on some other objects are equal to the ratio of the masses. Otherwise, if you want to know the difference in absolute terms (subtracting one force minus the other), you would also have to know the mass of the other object on which they act, as well as the distance. Regarding only the force of gravity ON these two objects . . . -- Assume both objects are in the same place, and that place is on or near the Earth's surface. -- The force of gravity on the more-massive object is (Mbig G) = (23.5)(9.8) -- The force of gravity on the less-massive object is (Mlittle G) = (14.7)(9.8) -- The difference between the two forces is (23.5 - 14.7)(9.8) = 86.3 newtons (about 19.4 pounds).
gravity and air resistance both act on a free falling object.
The type of force that keeps an object such as the Earth moving in a circle is a combination of gravity and centrifugal force. Gravity wants to pull the object inward, but centrifugal force wants to push the object outward. This combination keeps objects going in a circular path. You could also say that, for objects such as a rock attached to a rope that is swung in circles, the forces are the tension of the rope opposing centrifugal force. This is essentially the same thing, except with different forces at work.
The force of gravity between two masses depends on the product of the masses. So if either of the masses is reduced, the force between them is reduced. The Earth has about 80 times as much mass as the moon has. So the force of gravity between the Earth and any object on it is going to be more than the force of gravity between the moon and the same object when the object is on the moon. The distance between the two objects is also involved in determining the force of gravity between them, but the above discussion of the mass is enough to answer the question.
The force that pulls an object toward earth also pulls the earth toward the object.The two forces are equal. Together, we refer to them as the force of gravity.