Two identical spherical soap bubbles collapses. If `V` is consequent change in volume of the contained air, `S` is the chage in the total surface area and `T` is the surface tension of the soap solution. Then (if`p_(0)` is atmospheric pressure and assume temperature to remain same in all the bubbles).

Two spherical soap bubble coalesce. If V is the consequent change in volume of the contained air and S the change in total surface area, show that 3PV+4ST=0 where T is the surface tension of soap bubble and P is Atmospheric pressure

Two spherical soap bubble collapses. If V is the consequent change in volume of the contained air and S in the change in the total surface area and T is the surface tension of the soap solution, then it relation between P_(0), V, S and T are lambdaP_(0)V + 4ST = 0 , then find lambda ? (if P_(0) is atmospheric pressure) : Assume temperature of the air remain same in all the bubbles

A charged soap bobbe having surface charge density sigma and radius r. If the pressure inside and outsides the soap bubble is the same, then the surface tension of the soap solution is

Two soap bubbles of radii a and b coalesce to form a single bubble of radius c . If the external pressure is P , find the surface tension of the soap solution.

Air is pushed into a soap bubble of radius r to double its radius. If the surface tension of the soap solution is S, the work done in the process is

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

What will be the work done in increasing the radius of soap bubble from r/2 to 2r, if surface tension of soap solution is T?

An isolated and charged spherical soap bubble has a radius 'r' and the pressure inside is atmospheric. If 'T' is the surface tension of soap solution, then charge on drop is:

The amount of work done in blowing a soap bubble such that its diameter increases from d to D is (T=surface tension of the solution)

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