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.
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.
Yes. Mass is constant for a given object. Weight is a function of mass and gravity, stronger gravity more weight.
Terminal velocity defines the point at which an object will no longer accelerate. When a falling object reaches terminal velocity, it will continue to fall at a constant speed.
That's the acceleration of gravity. It depends on the distance from the primary object it refers to. It's as constant as that distance is.
The acceleration of gravity due to a single object is(Universal gravitational constant) x (Mass of the object)/(distance from the object's center of mass)2
nothing happens to it, it stays constant.
The gravity from a specific object (for example, the Sun) will become weaker if you go farther away from that object. The law of gravitation in general, and the gravitational constant, seems to be the same everywhere in the Universe.
yes..slow it down from the constant weight of the gravity it self
Yes. Mass is constant for a given object. Weight is a function of mass and gravity, stronger gravity more weight.
No, mass remains constant.
Terminal velocity defines the point at which an object will no longer accelerate. When a falling object reaches terminal velocity, it will continue to fall at a constant speed.
That's the acceleration of gravity. It depends on the distance from the primary object it refers to. It's as constant as that distance is.
The acceleration of gravity due to a single object is(Universal gravitational constant) x (Mass of the object)/(distance from the object's center of mass)2
weight is defined as the product of mass and gravity constant. as the value of gravity changes weight is also changed
Mass does since it is the amount of matter in an object and it is the same everywhere. Weight is the amount of gravity force on the object, so it changes on a different planet.
gravity force=G*m1*m2/r^2. this well known formula can be used to measure the gravity force in a particular distance from the object with mass m1.
Yes because of gravity
nothing happens to it, it stays constant.