No.
However at that altitude, it is likely there are some forces of acceleration acting on the object which will affect it.
An object will continue to orbit Earth at a certain distance above its surface, as long as its velocity counteracts the gravitational pull of Earth. This is known as achieving orbit, where the object remains in free fall around Earth due to a balance between its forward momentum and the pull of gravity.
The force with which an object is pulled towards the Earth due to gravity is called weight. Weight is the force exerted on an object by gravity, and it depends on the mass of the object and the acceleration due to gravity at that location.
The force of gravity acting on an object when it is sitting on the Earth is simply referred to as the object's weight. This force is what keeps the object anchored to the surface of the Earth.
The force of gravity between Earth and an object located on Earth is measured by the object's mass and the distance between the object and the center of the Earth. This force is commonly measured using the formula F = mg, where F is the force of gravity, m is the object's mass, and g is the acceleration due to gravity (9.8 m/s^2 on Earth).
The force between an object and Earth's gravity pulling on it is the object's weight. This force is determined by the mass of the object and the acceleration due to gravity (9.8 m/s^2 on Earth). The weight is the product of the mass and acceleration due to gravity: weight = mass × acceleration due to gravity.
Earth pulls on the object, and the object pulls on Earth
No. The mutual forces of gravity between the Earth and an object are exactly the same when the object is underwater as they are when it's above water. But when the object is underwater, there's an upward buoyant force on it, which compensates and cancels some or all of the gravitational force.
Yes. Gravity is a constant force. It never changes as long as you are within it's pull.
An object will continue to orbit Earth at a certain distance above its surface, as long as its velocity counteracts the gravitational pull of Earth. This is known as achieving orbit, where the object remains in free fall around Earth due to a balance between its forward momentum and the pull of gravity.
It is gravity.
There is no boundary where Earth's atmosphere is constrained by gravity. Many feel that astronauts orbiting above the Earth are weightless because they are far away from Earth's gravity , but weightlessness is actually caused by the free-falling of an object that is in orbit.
Mass is the source of Earth's gravity. Any object that has mass has gravity.
The force with which an object is pulled towards the Earth due to gravity is called weight. Weight is the force exerted on an object by gravity, and it depends on the mass of the object and the acceleration due to gravity at that location.
gravity
gravity
The force of gravity acting on an object when it is sitting on the Earth is simply referred to as the object's weight. This force is what keeps the object anchored to the surface of the Earth.
The potential energy of a mechanical object in relation to gravity is dependent on the mass of the object, and the height of the object above the earth. Generally represented by this equation: PE=mgh