no it does not
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.
The force of gravity on Saturn is weaker than on Earth. Gravity is determined by both the mass of the planet and the distance from its center, and Saturn has a lower mass and larger radius compared to Earth, resulting in weaker gravitational force on its surface.
Earth's gravitational force is stronger than Uranus due to Earth's larger mass and size. Uranus has a weaker gravitational force because it is a gas planet with lower density than Earth.
The centripetal force is equal to the gravitational force when a particular body is in a circle. For a body that is in an orbit, the gravitational force is equivalent to the centripetal force.
An astronaut weighs less on the moon because the moon has less mass than Earth, meaning weaker gravitational force. Weight is the result of the gravitational force acting on an object's mass, so with less force on the moon, the astronaut feels lighter.
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.
The mass of the object generating the gravitational field and the distance the observer is from it (i.e., the radius of the object).
The force of gravity exerted by an object is directly proportional to the mass of an object: it exerts this force on other matter, while the gravity of other matter also exerts a force.The formula is: F= G * m1m2/r squared - G is the gravitational constant, m1 and m2 masses, and r the distance between them (their centers of mass)Where, however, one object is much more massive, the acceleration induced by the larger object (e.g. Earth) is negligibly different for small objects of different mass, so that while the force is greater on larger objects, the accelerations are the same.
The gravitational force between two objects increases with their masses; the larger the masses, the stronger the force. Additionally, the gravitational force decreases with distance; the farther apart the objects are, the weaker the force between them.
The gravitational force acting on an object is directly proportional to its mass. Therefore, the size of an object, which is related to its volume, can impact the gravitational force acting upon it. Larger objects with greater mass will experience a stronger gravitational force compared to smaller objects with less mass.
A heavier object experiences a greater gravitational force than a lighter object due to its larger mass. Gravity is directly proportional to mass; the greater the mass, the greater the gravitational force.
An object with a larger mass would be more affected by gravitational force, as the force of gravity is directly proportional to the mass of the object. Therefore, an object like a planet or a star with a significant mass would experience a stronger gravitational force compared to a smaller object like a pebble.
The truck has a greater gravitational force than an egg. Gravitational force depends on the mass of an object, so the truck’s larger mass leads to a greater gravitational force compared to the egg.
By the inverse square
The gravitational force between two objects increases with mass: the larger the mass, the stronger the gravitational force. The force decreases with distance between the two objects: the farther apart they are, the weaker the gravitational force.
The force of gravity on Saturn is weaker than on Earth. Gravity is determined by both the mass of the planet and the distance from its center, and Saturn has a lower mass and larger radius compared to Earth, resulting in weaker gravitational force on its surface.
Earth's gravitational force is stronger than Uranus due to Earth's larger mass and size. Uranus has a weaker gravitational force because it is a gas planet with lower density than Earth.