Consider a rain drop falling at terminal speed. For what radius `(R)` of the drop can we disregard the influence of gravity on its shape? Surface tension and density of water are `T` and `rho` respectively.

A drop of radius r is broken into n equal drips. Calulate the work done if surface tension of water is T.

The excess pressure inside the drop of a liquid of surface tension T and radius of drom r is

The time period (T) of small oscillations of the surface of a liquid drop depends on its surface tension (s), the density (rho) of the liquid and it's mean radius (r) as T = cs^(x) rho^(y)r^(z) . If in the measurement of the mean radius of the drop, the error is 2 % , the error in the measurement of surface tension and density both are of 1% . Find the percentage error in measurement of the time period.

Calculate the heat evolved for the rise of water when one end of the capillary tube of radius r is immeresed vartically into water. Asssume surface tension =T and density of water to be rho

A water drop of radius R is split into n smaller drops , each of radius r. If T is the surface tension of water ,then the work done in the process is

1000 small drops of water each of radius 'r' are joined together to form a single drop of water During the process the change in energy has raised the temerature . If T is the surface tension of the water , d is density , the rise in temperature is

Internal pressure inside a liquid drop of radius r and surface tension T is

Two mercury drops (each of radius r) merge to form a bigger drop. The surface energy of the bigger drop, if T is the surface tension is

n' droplets of equal of radius r coalesce to form a bigger drop of radius R. The energy liberated is equal to ( T = Surface tension of water )