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The relationship between the mass of a planet and its relative strength of gravitational pull is that they are directly proportional. The equation for the force of gravity between two bodies is F = GMm/r^2, where F is the force of gravity, G is the gravitational constant, M is mass 1, m is mass 2, and r is the distance between the objects.
The larger the surface area, the larger the damping of an oscillation
The bigger an object's mass is, the bigger its gravitational pull is. Earth's gravitational pull is larger because it has a bigger mass.
If the radius is larger, the surface will also be larger. As a functional dependency, you only need one - the radius, or the surface - whatever.
Below the earths surface.
The larger the mass, the stronger the gravitational force.
The larger the mass, the stronger the gravitational force.
It exerts a stronger force on us (when we are on it's surface) for two reasons: 1. It has a larger mass (gravitational field strength increases with mass). 2. It is closer (gravitational force is inversely proportional to the square of the distance from the object's centre of gravity).
The relationship between the mass of a planet and its relative strength of gravitational pull is that they are directly proportional. The equation for the force of gravity between two bodies is F = GMm/r^2, where F is the force of gravity, G is the gravitational constant, M is mass 1, m is mass 2, and r is the distance between the objects.
If the Earth were a (homogeneous) sphere, the gravitational force on its surface would be the same everywhere. I think that the gravitational force is slightly larger at the equator (center bulging Earth). But you might not measure it because of the rotation of the Earth.
To give a larger surface area, increasing the strength of the hold
Gravitational force of the moon is 1/6th the gravitational force of the Earth. The larger the object, the greater gravitational force it will have.
no it does not
Latitude, altitude, and the local topography and geology. Effect the gravitational pull of an area. In open areas, gravitational pull is lowest on the Nevado Huascaran mountain in Peru, and highest on the surface of the Arctic Ocean. In larger cities, the lowest gravitational pull is in Kuala Lumpur, Mexico City, and Singapore, with the highest being in Oslo and Helsinki.
Because the gravitational pull of the Earth is much larger than the gravitational pull of lets say... a human. You could argue that on earth there is a gravitational pull to humans, but the Earth is over powering that pull. So the object is pulled down (to the surface of the Earth) rather than to you or me.
All obects have a gravitational pull. The larger it is, the stronger the pull.
It is 21/23.