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Mass does not depend on gravity. At zero gravity the object will have the same mass as at a higher gravity. What changes is the object's weight. The fact that the object still has mass can be ascertained from its inertia - it will take a force to make it move, or to stop it.Mass does not depend on gravity. At zero gravity the object will have the same mass as at a higher gravity. What changes is the object's weight. The fact that the object still has mass can be ascertained from its inertia - it will take a force to make it move, or to stop it.Mass does not depend on gravity. At zero gravity the object will have the same mass as at a higher gravity. What changes is the object's weight. The fact that the object still has mass can be ascertained from its inertia - it will take a force to make it move, or to stop it.Mass does not depend on gravity. At zero gravity the object will have the same mass as at a higher gravity. What changes is the object's weight. The fact that the object still has mass can be ascertained from its inertia - it will take a force to make it move, or to stop it.
inertia is a plant
No. An object that has a lot of mass and is hard to move has inertia.
matter is not related to inertia. Mass is.
No. The weight by an object is related to the object's mass. Inertia is a separate effect, also due to mass - but there is no such thing as a "pull of inertia".
Nothing gives an object inertia. Inertia is not a force. It is just the tendency of an object to continue in its motion if there is no force acting upon it.
Zero gravity does not affect inertia. The inertia of an object is an inherent property of the object and is directly proportional to the object's mass.
inertia. the more mass an object has, the greater its inertia. what do you call it when an object refuses a object in motion?
Inertia is the resistance of any physical object to a change in its state of motion. It is represented numerically by an object's mass. The more mass an object has, the greater its inertia.
Rotational inertia is sometimes called spin. It involves the movement of a mass around an axis. This moving mass will have some measure of kinetic energy that is due to the fact that it is spinning. The variables are the shape and the mass of the object, the way the mass is distributed within the object, the speed of its rotation, and the location of the axis of spin through the object. The moment of inertia might also be called angular mass, mass moment of inertia, rotational inertia, or polar moment of inertia of mass. Use the link below for more information.
Inertia does not vary from place to place. Inertia is simply the tendency of an object to resist changing its state. Inertia (and, by extension, momentum) only vary in relation to the mass of an object, not where the object is located.
Inertia refers to the resistance of an object when there is a change in the motion of the object. The more inertia the object has, the more mass it will have.