The pressure of a fluid varies with depth h as `P = P_0 + rho gh` , where `rho` is the fluid density. This expression is associated with

The density rho of a liquid varies with depth h from the free surface as rho=kh . A small body of density rho_(1) is released from the surface of liquid. The body will

It P is the pressure and rho is the density of a gas, then P and rho are realted as :

Density of a liquid varies with depth as rho=alpha h. A small ball of density rho_(0) is released from the free surface of the liquid. Then

A small ball of density 4rho_(0) is released from rest just below the surface of a liquid. The density of liquid increases with depth as rho=rho_(0)(1+ay) where a=2m^(-1) is a constant. Find the time period of its oscillation. (Neglect the viscosity effects).

An ideal gas equation can be written as P = rho R T/ M_0 where rho and M are resp.

A uniform solid sphere of radius R is in equilibrium inside a liquid whose density varies with depth from free surface as rho=rho_(0)(1+h/(h_(0))) where h is depth from free surface. Density of sphere sigma will be :

A small air bubble of radius r in water is at depth h below the water surface. If P_0 is the atmospheric pressure, rho is the density of water and T is the surface tension of water, what is the pressure inside the bubble?

Derive an expression for fluid pressure.

A small air bubble of radius r in water is at a depth h ( r lt lt h ) . If P_(o) is the atmospheric pressure, rho is the density of water and T is the surface tension of water, the excess pressure inside the bubble over the pressure outside it is