The absolute pressure at a depth h below the surface of a liquid of density `rho` is [Given `P_(a)` = atmospheric pressure, g = acceleration due to gravity]

The pressure at depth h below the surface of a liquid of density rho open to the atmosphere is

The pressure at a depth h in a liquid of density d is given by pressure = __ , where g is the acceleration due to gravity.

If the atompspheric pressure is P _(a) then the jpressure P at depth a below the surface of a liquid of density rho open to the atmosphere is

An air bubble is formed at depth h below the surface of water. The pressure inside the bubble is- ( P_(0)= atmospheric pressure, r = radius of bubble)

A solid sphere of radius r is floating at the interface of two immiscible liquids of densities rho_(1) and rho_(2)(rho_(2) gt rho_(1)) , half of its volume lying in each. The height of the upper liquid column from the interface of the two liquids is h. The force exerted on the sphere by the upper liquid is (atmospheric pressure = p_(0) and acceleration due to gravity is g):

The acceleration due to gravity at a depth R//2 below the surface of the earth is

Find the total pressure inside a sperical air bubble of radius 0.2 mm. The bubble is at a depth 5 cm below the surface of a liquid of density 2 xx 10^(3) kg m^(-3) and surface tension 0.082 N m^(-1) . (Given : atmospheric pressure = 1.01 xx 10^(5) Nm^(-2) ) Hint : P_(i) = P_(o) + (2S)/(R) P_(o) = atmospheric pressure + gauge pressure of liquid column.

Calculate the pressure inside a small air bubble of radus r situated at a depth h below the free surface of liquids of densities rho_(1) and rho_(2) and surface tennsions T_(1) and T_(2) . The thickness of the first and second liquids are h_(1) and h_(2) respectively. Take atmosphere pressure =P_(0) .

An air bubble of radius r in water is at a depth h below the water surface at some instant. If P is atmospheric pressure, d and T are density and surface tension of water respectivley . the pressure inside the bubble will be :