BUOYANCY AND DISPLACEMENT
It was Archimedes who first realised, in his βeurekaβ moment, that a body that is immersed completely in water will displace a volume of water equal to the volume of the body and that the apparent weight of the body, when immersed, will be reduced by the weight of water displaced.
If the body weighs less than the weight of a volume of water equal to its own volume, then it will not become immersed completely. It will float with part of its own volume above the water surface such that the weight of the displaced water equals the weight of the body. Thus a body, floating freely in water, will be acted upon by forces due to the water pressure at each point of its wetted surface and we can proceed to prove that Archimedes was right.
The resultant of these forces will be an upward force equal to the weight of the water displaced by the body. This is the bodyβs displacement, often denoted by the symbol Ξ. If the water density is Ο then the pressure acting upon a small area Ξ΄A will be Οh and the force will be ΟhΞ΄A. By integrating over the whole of the wetted surface the total force on the body is Ξ£ΟhΞ΄A = ΟV where V is the volume of the body below water (called the volume of displacement). This is termed the buoyancy force, or simply the buoyancy. For equilibrium this force must act vertically as any resultant horizontal force would cause the body to move in the direction of that resultant. Also for equilibrium the buoyancy force must be equal and opposite to the weight of the body. If it were not the body would move up or down. The two forces must act in the same line otherwise there would exist a moment causing the body to rotate. Another way of looking at this is to consider the body removed and replaced by a volume of water, surrounded by a weightless membrane of the same shape as the bodyβs underwater form. The water surface will be horizontal and the forces on the membrane will support the weight of water within.
