Frequency is the function of density `(rho)` , length `(a)` and surface tension `(T)` . Then its value is

Frequency is the function of density rho , length lambda and tension T . The period of oscillation is proporttional to

The frequency (V) of an oscillatingj drop may depends upon radius (r ) of the drop density (rho) of liquid and the surface tension (S) of the liquid. Deduce of formula dimensionally.

A sphere of density rho is half submerged in a liquid of density sigma and surface tension T. The sphere remains in equilibrium. Find radius of the sphere (assume the force due to surface tension acts tangentially to surface of sphere)

The correct graph between the frequency n and square root of density rho of a wire, keeping its length, radius and tension constant, is

A liquid drop of radius R breaks into N smaller droplets of radii r, If liquid has density rho, specific heat s and surface tension, T, than the drop in temeperature is given

A vertical U-tube contains a liquid of density rho and surface tension T. if the radius of the meniscus of liquid in the limbs of the U-tube are R_(1) and R_(2) find the difference in the liquid column in the limbs.

A spherical liquid drop is placed on a horizontal plane . A small distrubance cause the volume of the drop to oscillate . The time period oscillation (T) of the liquid drop depends on radius (r) of the drop , density (rho) and surface tension tension (S) of the liquid. Which amount the following will be be a possible expression for T (where k is a dimensionless constant)?