There's no relationship between the weight of an object in air and the buoyant
force on it when it's in water.
The buoyant force is equal to the weight of the water the object displaces,
which depends directly on its volume.
Two objects that have identical weight in air will experience radically different
buoyant forces in water if their volumes are different.
In the general case, these are quite unrelated; the buoyant force is related to the object's volume, not its weight. Or the part of the volume that is submerged in the liquid or gas. However, if the object is freely floating, then the buoyant force will be equal to its weight.
The relationship between buoyant force and weight was first stated by Archimedes.
Archimedes first stated the relationship between buoyant force and weight of a displaced fluid.
They are equal
The buoyant force on any object in water is equal to the weight of the displaced water, regardless of how much of the object is submerged.
In the general case, these are quite unrelated; the buoyant force is related to the object's volume, not its weight. Or the part of the volume that is submerged in the liquid or gas. However, if the object is freely floating, then the buoyant force will be equal to its weight.
The relationship between buoyant force and weight was first stated by Archimedes.
The submerged will float
Archimedes first stated the relationship between buoyant force and weight of a displaced fluid.
They are equal
The buoyant force on any object in water is equal to the weight of the displaced water, regardless of how much of the object is submerged.
Buoyant force is equal to the weight of the water displaced.
The buoyant force is equal to the weight of the displaced water.
No, but the difference between the buoyant force and the weight of the object will determine whether it floats or sinks.
It is stationary, regardless of where it is.
No.
They are equal.