You cannot feel the gravitational attraction between you and an object because the force of gravity is very weak compared to the other forces acting on you (such as electromagnetic forces). Additionally, other factors like the Earth's gravitational field are much stronger, so you are not as sensitive to the gravitational attraction between you and smaller objects.
Because the gravitational attraction between each person and the earth is far greater than that between the two people. Gravitational force between two objects is proportional to the mass of each object. The mass of the earth is far far greater than that of a pesron.
Apparent weightlessness occurs when an object is in free fall, making it feel weightless due to the absence of support forces. True weightlessness occurs when an object is at a point in space where the gravitational pull is negligible, resulting in a complete absence of gravitational forces acting on the object.
An object feels lighter underwater because of the buoyant force exerted on it by the water. This force counteracts the gravitational force acting on the object, making it feel lighter.
When you hold an object against the pull of gravity, you feel a sensation of weight in your hand due to the force required to counteract gravity. This feeling can vary depending on the mass of the object and the strength of the gravitational force acting on it.
You do not feel a gravitational tug from a person passing you on the street because the gravitational force between two people is extremely small compared to the force of gravity between us and the Earth. The force of gravity between two people is too weak to be noticeable in everyday situations.
Because the gravitational attraction between each person and the earth is far greater than that between the two people. Gravitational force between two objects is proportional to the mass of each object. The mass of the earth is far far greater than that of a pesron.
No. There is a gravitational force of attraction between every two masses in the universe. The strongest pair of forces you feel is the pair between you and the earth, which you call your "weight". It would be there even if the sun were not there.
When the gravitational force acting on an object changes, the object's weight may change accordingly. If the force increases, the object will feel heavier, and if the force decreases, the object will feel lighter. This change in gravitational force can also impact the object's motion and trajectory if it is in free fall or orbit.
The gravitational attraction between two people is extremely small because the force of gravity between two objects depends on their mass and distance. For two average-sized people standing a few feet apart, the gravitational force would be negligible compared to the other forces acting on them.
Apparent weightlessness occurs when an object is in free fall, making it feel weightless due to the absence of support forces. True weightlessness occurs when an object is at a point in space where the gravitational pull is negligible, resulting in a complete absence of gravitational forces acting on the object.
because for attraction mass of one object should be greater than other
An object feels lighter underwater because of the buoyant force exerted on it by the water. This force counteracts the gravitational force acting on the object, making it feel lighter.
When you hold an object against the pull of gravity, you feel a sensation of weight in your hand due to the force required to counteract gravity. This feeling can vary depending on the mass of the object and the strength of the gravitational force acting on it.
Galaxies do exert significant gravitational attraction on other galaxies. For example, the Greater and the Lesser Magellanic Clouds are galaxies that orbit our own galaxy, the Milky Way. In that sense, the stars in one galaxy do have a gravitational interaction with those in other galaxies. Of course, the more distant galaxies have correspondingly less gravitational interaction with ours.
the magnet's magnetic force (attraction) won't cause cause gravity. however, all objects impose a gravitational pull on other objects, but they can be so weak that we can not feel it. only objects of astronomical mass like the Earth can we feel it's gravititational pull. therfore, the magnet's magnetic force won't cause a gravitational pull, however the object itself would (if very small)
Objects with a higher mass experience the strongest pull of attraction towards the Earth due to gravity. The force of gravity is directly proportional to an object's mass, so objects with a larger mass will have a greater gravitational pull toward the Earth.
Because the object's inertial motion is equal to the gravitational acceleration. Weight equals mass times gravitational acceleration (W=mg), so you would feel weightless, but your mass stays the same.