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.
Its mass. Greater the mass more the inertia
inertia.
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.
The moment of inertia of a body about an axis of rotation is a measure of its resistance to rotational motion. It depends on the mass of the body and how that mass is distributed around the axis of rotation. A body with a larger moment of inertia requires more torque to rotate at the same rate as a body with a smaller moment of inertia.
The amount of inertia of a body is determined by its mass - the greater the mass, the greater the inertia. Inertia also depends on the distribution of mass within the body - objects with more of their mass concentrated towards the outer edges have greater inertia. Additionally, the shape and size of an object can affect its inertia - larger and more compact objects tend to have more inertia.
Its mass. Greater the mass more the inertia
inertia.
The inertia of a body can be defined as the relunctance of a body to acceleration. The mass of a body can be defined as a measure of the inertia of a body. This is because acceleration = resultant force / mass. So, if mass is greater, the less will be the acceleration of the body and hence the greater the inertia.
amount of inertia of body depends upon mass of that body
Its mass. Greater the mass more the inertia
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.
Not a single body is present in this universe without mass but they can be weight less.By definition, mass is the measure of the inertia of a body, so if the body were without mass (as some particles, for example), it would have no inertia.
The moment of inertia of a body about an axis of rotation is a measure of its resistance to rotational motion. It depends on the mass of the body and how that mass is distributed around the axis of rotation. A body with a larger moment of inertia requires more torque to rotate at the same rate as a body with a smaller moment of inertia.
The amount of inertia of a body is determined by its mass - the greater the mass, the greater the inertia. Inertia also depends on the distribution of mass within the body - objects with more of their mass concentrated towards the outer edges have greater inertia. Additionally, the shape and size of an object can affect its inertia - larger and more compact objects tend to have more inertia.
is a resisstance of a body is called inertia
inertia simply depends upon mass.
d body inreases in mass 2 witstand d inertia force