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gravity
It's what we have learned to call "weight".
The forces of gravity between every two objects attract the objects toward each other. So I guess you'd call that a 'pulling force'.
No, that's not correct at all.First ... the mass of an object doesn't change. What changes is the force between that objectand any other object with mass. That force is what we call the "weight" of the objects.Also ... it's very misleading to talk about "how much gravity is pulling". The force of gravity actsbetween two masses. The forces are always equal on both objects, and the strength of the forcedepends on both masses.
gravity is a force that pulls us on to the ground and earth makes the gravity.In space there is no gravity (scientist call this zero gravity) so gravity isn't pulling the universe back because there is no gravity outside planets.
Gravity is a force measured in Newton's (N)
There is no special name for that. Physics is usually just concerned with "forces", and doesn't specify whether the force pushes or pulls. If you want to be more specific, you can just call it a "pulling force".There is no special name for that. Physics is usually just concerned with "forces", and doesn't specify whether the force pushes or pulls. If you want to be more specific, you can just call it a "pulling force".There is no special name for that. Physics is usually just concerned with "forces", and doesn't specify whether the force pushes or pulls. If you want to be more specific, you can just call it a "pulling force".There is no special name for that. Physics is usually just concerned with "forces", and doesn't specify whether the force pushes or pulls. If you want to be more specific, you can just call it a "pulling force".
Most folks call that the object's weight.
That is called a centripetal force.
Gravity.
Weight.
In an application like this, the g is actually g or the force of gravity (earth's gravity at sea level). High g is high gravity, and it may be used in reference to something like, say, the experiences of a fighter pilot who is flying nose down and has to "pull out" of the dive. As he pulls out, the effects of the change in velocity put extra stress on his body, and it is like having more gravity pulling on him, or "high g" pulling on him when he is pulling out. In a really sharp turn (a bank) at high speed, the same high g effects will come to call. Some amusement park rides afford passengers the same experience.