Because in space its makes things float
the gravity on the moon is far less than on the earth, which means that the object will exert less force downwards on your arms, meaning it is easily lifted.
No one lifted the earth, but Archimedes (a great scientist and mathematician) claimed that he could do it.
Because there is a force of gravity constantly pulling it towards the center of earth. When you exert enough force to over come the gravity acting on an object it is lifted
The question seems, well, awkward. But I will attempt it. If you are asking if gravity still has an effect on a lifted object, than yes. This is why that object will fall to the ground when dropped or from the object lifting it. Gravity always has an attractive force on every object in the universe. Any 2 objects that contain matter attract each other. You are attracted to your computer. Now, why doesn't the computer fly towards you? This is because gravity's effect is very, very weak. The more mass an object has, and the closer that object is, the more gravity has an effect. That is why it takes objects the size of moons, planets, and stars to have a noticeable effect on other objects. Gravitational pull on Earth: 9.8 Newtons Gravity of Earth's moon: 1.6 Newtons
Earth pulls on the object, and the object pulls on Earth
They can go to places that we can't go. They can process and return data to Earth easily. They can study things in space easier because they are clear of the Earth's atmosphere.
ellie mcdonald can not lift 200 grams
The force of gravity that attracts an object on Earth toward the Earth is the object's weight on Earth. The force of gravity that attracts the Earth toward an object on it is the Earth's weight on the object. Both forces are always there, and they're equal.
the object that is nearest to earth is moon
Weight is the measure of the earth's pull of an object.
It's called "a 13-lb object" because it weighs thirteen pounds. Since we are on earth we must assume that the object referred to is also here. Just like everything else, the object could very easily have a different weight on a different planet.
Work = energy (by the Work-Energy Equivalence Theorem).The work done in lifting an object shows up as the gravitational potential energy of the object: W = mgh, where W is the work done; m is the object's mass; g is the acceleration due to Earth's gravity; and h is the height to which the object is lifted. (This assumes that the lifting is done near Earth's surface, with gravity effectively constant.)ALL Credit goes to Argent at yahoo answers