The magnitude of acceleration due to gravity depends on the mass of the object
toward which you're attracted by gravity, and on your distance from it. There are
trillions of different possibilities in space.
Acceleration due to gravity on Saturn = 11.171 m/s2 (9.807 m/s2 on Earth)
Weight depends on acceleration due to gravity and similarly acceleration due gravity depends on force of gravity. The force of gravity of moon is 6times less than that of earth and due to this their is variation in acceleration due to gravith between the earth and the moon. As there is difference in acceleration due to gravity between the earth and moon, the magnitude of weight also vary . And next most important thing to keep on mind is that mass is independent of gravity so it does not change anywhere ....
No. Acceleration due to gravity on the moon is roughly 1/6 of that on Earth.
The acceleration of gravity ... on or near the Earth, for example ... is inversely proportional to the square of the distance from the center of the Earth. So it diminishes as you rise from the surface. When you have ascended to an altitude of one Earth radius ... about 4,000 miles ... your distance from the center is then two Earth radii, so the acceleration of gravity has shrunk to 1/4 of its value on the surface.
The mass of an astronaut in space does not change, except for the minor changes that occur due to change in exercise and eating. Mass is mass, and represents the amount of material in an object. His weight, however, does change, because weight is mass times the acceleration due to gravity, and gravity does indeed change.
9.98
No effect. All masses experience the same acceleration due to gravity.
Acceleration due to gravity on Saturn = 11.171 m/s2 (9.807 m/s2 on Earth)
Newton.
The acceleration due to gravity from any given object decreases with distance from it. Specifically, gravity scales with the inverse of the square of the distance. That means, for example, if you double your distance, gravitational acceleration is reduced to a quarter of what it was. Most areas of space are quite empty, far from any massive objects, which means that acceleration due to gravity will be quite small. Conversely, some areas of space that are very near massive objects can have enormous gravitational acceleration.
The acceleration of gravity due to a single object is(Universal gravitational constant) x (Mass of the object)/(distance from the object's center of mass)2
acceleration due to gravity of earth is 9.8ms-2
The magnitude of acceleration due to gravity depends on the mass of the object toward which you're attracted by gravity, and on your distance from it. It ought to be pretty clear that in space, there are several different possibilities.
Actually the number stated is only an approximate number. The exact value depends on where you are on the earth and even where the sun and moon are in relation to you. Astronauts above the earth experience microgravity and as a space probe moves away from the earth, the acceleration of gravity decreases. Even on the surface of the earth, the acceleration due to gravity varies - depending on the density of the material underneath.
Near Earth, the acceleration due to gravity is approximately 9.8 meters per square second. It varies slightly from place to place, though.
On Earth, it's 9.81 m/s2 . (rounded)
The accepted value for acceleration due to gravity is 9.8 m/s2 (9.8 metres per second, per second)