That's because inertia does not depend on weight.
An object's mass causes two effects:
One is the gravitational interaction (force) with other masses. This is proportional to both masses (also, the force decreases with distance).
The other is inertia - if an object has mass, then it requires an effort to change its velocity.
Inertia depends on the mass - NOT on the weight. Weight also depends on the mass. However, weight also depends on the mass of other objects - for example, on Earth, our weight depends on the gravitational field of planet Earth.
Yes, a weightless body can still have inertia. Inertia is the resistance of an object to changes in its motion, and it is determined by the mass of an object rather than its weight. Even if a body has no weight due to being weightless in space, it will still have inertia based on its mass.
An astronaut has to exert a force on a weightless object in order to move it because in space, there is no gravity to naturally pull or push objects. Therefore, the astronaut must apply force to overcome inertia and move the object.
Inertia is directly related to an object's mass, which is a property of matter. The greater the mass of an object, the greater its inertia, meaning it resists changes in its motion. Different types of matter have different masses and therefore exhibit different levels of inertia.
A truly weightless object experiences no gravitational force, such as an object in deep space far from any massive body. An object that is weightless due to free fall is still under the influence of gravity but is in a state of free fall where the force of gravity and the acceleration of the object cancel out, making it feel weightless.
The mass of the object and the velocity of the object.
Yes, a weightless body can still have inertia. Inertia is the resistance of an object to changes in its motion, and it is determined by the mass of an object rather than its weight. Even if a body has no weight due to being weightless in space, it will still have inertia based on its mass.
An astronaut has to exert a force on a weightless object in order to move it because in space, there is no gravity to naturally pull or push objects. Therefore, the astronaut must apply force to overcome inertia and move the object.
Inertia is directly related to an object's mass, which is a property of matter. The greater the mass of an object, the greater its inertia, meaning it resists changes in its motion. Different types of matter have different masses and therefore exhibit different levels of inertia.
A truly weightless object experiences no gravitational force, such as an object in deep space far from any massive body. An object that is weightless due to free fall is still under the influence of gravity but is in a state of free fall where the force of gravity and the acceleration of the object cancel out, making it feel weightless.
The mass of the object and the velocity of the object.
"inertia"
An object is considered weightless when there is no normal force acting on it because weight is the force exerted by gravity on an object's mass. In freefall, the object is only subject to the force of gravity, which causes it to accelerate with the same acceleration as the object itself, resulting in a sensation of weightlessness.
The mass of an object determines its inertia. Inertia is the resistance of an object to changes in its motion, and objects with greater mass have greater inertia.
In zero gravity, inertia would remain the same as in normal gravity. Inertia is a property of a body that causes it to resist changes in its motion, regardless of the presence or absence of gravity. Thus, objects in zero gravity would still exhibit the same resistance to changes in motion as they would in a gravitational environment.
the mass of an object. The greater the mass of an object, the greater its inertia. Additionally, inertia also depends on the velocity of the object - the faster an object is moving, the greater its inertia.
Inertia varies depending on an object's mass. The greater the mass of an object, the greater its inertia. The shape and size of an object can also affect its inertia.
An objects mass is a measure of its inertia.