`A` soap bubble has radius `R` and thickness `d(ltltR)` as shown. It colapses into a spherical drop. The ratio of excess pressure in the drop to the excess pressure inside the bubble is

The excess pressure inside a soap bubble is

Describe an experiment to demonstrate the excess pressure inside a soap bubble.

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

Two liquid drop have diameters of 1 cm and 1.5 cm. The ratio of excess pressures inside them is

The ratio of radii of two bubbles is 2 : 1 . What is the ratio of excess pressures inside them ?

The soap bubble formed at the end of the tube is blown very slowly. Draw the graph between excess of pressure inside the bubble with time.

Deduce expressions for the excess pressure inside a : (i) liquid drop, (ii) soap bubble.

The radii of two air bubbles are in the ratio 4 : 5. Find the ratio of excess pressure inside them. Also compare the works done in blowing these bubbles.

An air bubble of radius 1 mm is located at a depth of 20 cm below water level. The excess pressure inside the bubble above the atmospheric pressure is [Given, the surface tension of water is "0.075 Nm"^(-1) and density is "1000 kg m"^(-3) ]

Molecular forces exist between the molecules of a liquid in a container. The molecules on the surface have unequal force leading to a tension on the surface. If this is not compensated by a force, the equilibrium of the liquid will be a difficult task. This leads to an excess pressure on the surface. The nature of the meniscus can inform us of the direction of the excess pressure. The angle of contact of the liquid decided by the forces between the molecules, air and container can make the angle of contact. If the excess pressure in a soap bubble is p , the excess pressure in an air bubble is