In classical physics, weight is the force exerted on an object due to gravity. If an object has zero mass, it would not experience weight as weight is proportional to mass. So, for a body to have zero weight, it would need to have zero mass.
An object with zero mass is more likely than an object with zero weight, since mass is an intrinsic property of matter, whereas weight is a force caused by gravity acting on an object's mass. A zero-weight object would require a lack of gravitational force, which is unlikely in most scenarios.
The weight of an object at infinity would be zero since there is no gravitational force acting on it at that distance.
Setting the pan to zero before placing an object ensures that the weight displayed reflects only the weight of the object being added, without any additional weight or interference from the pan itself. This allows for accurate measurement of the object's weight.
The weight of an object can be almost zero in space or during free fall because weight is the force of gravity acting on an object's mass. In the absence of gravity or when experiencing weightlessness, objects do not feel the gravitational force, resulting in a weight close to zero.
Zero.
In classical physics, weight is the force exerted on an object due to gravity. If an object has zero mass, it would not experience weight as weight is proportional to mass. So, for a body to have zero weight, it would need to have zero mass.
An object with zero mass is more likely than an object with zero weight, since mass is an intrinsic property of matter, whereas weight is a force caused by gravity acting on an object's mass. A zero-weight object would require a lack of gravitational force, which is unlikely in most scenarios.
The weight of an object at infinity would be zero since there is no gravitational force acting on it at that distance.
Setting the pan to zero before placing an object ensures that the weight displayed reflects only the weight of the object being added, without any additional weight or interference from the pan itself. This allows for accurate measurement of the object's weight.
The weight of an object can be almost zero in space or during free fall because weight is the force of gravity acting on an object's mass. In the absence of gravity or when experiencing weightlessness, objects do not feel the gravitational force, resulting in a weight close to zero.
The apparent weight of an object is zero when it is in free fall or weightless due to being in orbit. In these cases, the object experiences no normal contact force from a supporting surface, so it does not feel any weight.
Weight is the force exerted on an object due to gravity. Without gravity, there would be no weight experienced by an object.
The weight of a free falling object is not zero, but it is temporarily equal to zero during free fall because the only force acting on the object is gravity, and it is being cancelled out by the object's acceleration due to gravity. This results in the object appearing weightless during free fall.
It reduces the object's apparent weight,sometimes to zero and even beyond.
weight of an object is minimum when it is placed at the center of the earth because when an object is in the center ,it experiences gravitational pull from all the sides.thus the net weight of an object remains to be zero. +++ Possibly, but given that the centre of the Earth is unreachable and a ball of metal anyway, a more useful and achievable location for weightlessness is in Space!
In a floating object, the weight of the object is balanced by the buoyant force exerted by the fluid it displaces. This equilibrium occurs because the weight of the object is equal to the weight of the fluid it displaces, resulting in a net force of zero and causing the object to float.