Energy needed in breaking a drop of radius R into n drops of radius r, is where T is surface tension and P is atmospheric pressure.

The energy needed for breaking a drop of radius R into n drops each of radius r is

A number of droplets, each of radius r , combine to form a drop of radius R . If T is the surface tension, the rise in temperature will be

If R is the radius of a soap bubble and S its surface tension, then the excess pressure inside is

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 respectively . the pressure inside the bubble will be :

The excess pressure inside a soap bubble of radius R is (S is the surface tension)

If sigma be the surface tension, the work done in breaking a big drop of radius R in n drops of equal radius is

The work done to split a liquid drop id radius R into N identical drops is (taken sigma as the surface tension of the liquid)

If a drop of liquid breaks into smaller droplets, it result in lowering of temperature of the droplets. Let a drop of radius R, breaks into N small droplets each of radius r. Estimate the drop in temperature.

A soap bubble of raidus R is surrounded by another soap bubble of radius 2R , as shown. Take surface tension =S . Then the pressure inside the smaller soap bubble, in excess of the atmosphere presure will be

Work done in forming a liquid drop of radius R is W_(1) and that of radius 3R is W_(2) . The ratio of work done is