i reckon that it is right because according to newtons third law it explain that when force is exert on another object it will react with same magnitude so it might be right that it can apply same magnitude force as it has been apply.
The terms "gravitational force" and "force of gravity" are interchangeable and both refer to the same force exerted on objects due to gravity. When an apple is falling, the force of gravity (gravitational force) is indeed acting on it, causing it to accelerate towards the Earth.
Weight does not change with location, as weight is a measure of the gravitational force acting on an object and is the same everywhere on Earth. However, an object's mass remains constant regardless of location.
The moon keeps the same hemisphere facing Earth because the gravitational force between the two is equal to the centrifugal force, causing the moon to stay in a stable position.
An object's weight is a measure of the gravitational force acting on it, which varies depending on the object's mass and the strength of the gravitational field. Therefore, an object will weigh differently on different celestial bodies due to variations in their gravitational fields.
The gravitational force of Earth affects different masses in the same way by pulling them towards the center of the Earth with a force proportional to their mass. This means that objects of different masses will accelerate at the same rate towards the Earth due to gravity.
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.
No, essentially mass = gravity the earths mass is roughly 81 * that of the moon, if you stood at the same distance from both, the force on you from the earth would be 81 * that of the moon.
The earth is not perfect sphere therefore the radius differs from place to place and from Newton Gravitational law force is directly proportional to radius
The gravitational pull of the earth is pretty much the same anywhere between the poles and the equator creating a centripetal force pulling things in towards the earth.. However, the rotation of the planet results in an outward centrifugal force pushing things away from the earth. This force is greatest at the equator. Even though the gravitational pull is the same everywhere, the centrifugal force at the equator gives the impression of a very slightly lower gravitational pull.
The terms "gravitational force" and "force of gravity" are interchangeable and both refer to the same force exerted on objects due to gravity. When an apple is falling, the force of gravity (gravitational force) is indeed acting on it, causing it to accelerate towards the Earth.
The force of gravity is the same everywhere in the universe. What do you mean exactly? You can calculate the force of gravity between any two objects with the following formular Mass times (multiplied by) Mass divided by distance squared.
9.8 or 10 Newtons to be exact. The gravitational force stays the same as long as you are on earth.
The force of gravitation attracting the earth and moon toward each other is exactly the same force on both bodies.Just as the force of gravitation that attracts you toward the earth is exactly the same as the force that attractsthe earth toward you.
The gravitational constant "G" is the same everywhere. The force of gravity on the moon, expressed as the acceleration of a falling body is 1.62 metres/sec2. compared with 9.81 m/s2 on the earth.
The Earth and the object exert a gravitational force on each other, but only the Earth's is big enough to measure. So, the formula for gravitational force include the distance from one body's surface to its center and the same for the other body. The length of the radius is directly proportional to the body's gravitational force.
Weight does not change with location, as weight is a measure of the gravitational force acting on an object and is the same everywhere on Earth. However, an object's mass remains constant regardless of location.
The gravitational force from a planet on the sun is so small. For example, 1,000,000 Earths can fit in the sun. The mass of the sun is 333,000 times bigger than the Earth. It is the same way you on Earth. You have a gravitational force on the Earth but it is so small.