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10Acceleration due to gravity decreases with increase in height.
g is maximum at the Earth’s center.
The distance of a satellite from Earth’s center is R + h.
The value of g at Mount Everest is zero.
g at d = 2R is one-fourth of surface value.
Acceleration due to gravity depends on the mass of the falling object.
g on the Moon is less than g on Earth.
A satellite does not experience gravity.
g changes very little for small heights above Earth.
The Moon’s gravity is about six times weaker than Earth’s gravity.
Percentage: 0%
The radius of the Earth is 6371 km and the weight of an object on the Earth is 800 N. What is the weight of the object at a height of 6371 km from the surface of the Earth?
Acceleration due to gravity varies with:
If distance from Earth’s center becomes 2R, g becomes:
Acceleration due to gravity at ISS is approximately:
The formula for g at height h is:
g decreases with height because:
The value of g at the top of Mount Everest is:
Acceleration due to gravity on the Moon is:
Acceleration due to gravity is inversely proportional to:
A body weighs less at higher altitude because:
Acceleration due to gravity decreases as the ______ from the center of the Earth increases.
The formula for acceleration due to gravity at height h is ______ = GM/(R + h)².
At the Earth’s surface, acceleration due to gravity is ______.8 m/s².
When the distance from Earth’s center becomes ______, the value of g becomes one-fourth of its surface value.
A satellite orbits the Earth at a height because gravity provides the necessary ______ force.
The acceleration due to gravity at the height of the International Space Station is ______.66 m/s².
The value of g at the top of Mount Everest is ______ less than that at sea level.
The distance of a satellite from the center of the Earth is equal to ______ + h.
The acceleration due to gravity on the Moon is ______.62 m/s².
The acceleration due to gravity of the Moon is about ______ times less than that of the Earth.