The time period of a soap bubble is T which depneds on pressure p density d and surface tension s then the relation for T is

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)?

Time period of an oscillating drop of radius r, density rho and surface tension T is t=ksqrt((rhor^5)/T) . Check the correctness of the relation

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.

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 one soap bubble is three times that inside a second soap bubble, then the ratio of their surface area is:

Under isothermal condition two soap bubbles of radii r_(1) and r_(2) coalesce to form a single bubble of radius r. The external pressure is p_(0) . Find the surface tension of the soap in terms of the given parameters.

Statement-1 : If there is a soap bubble in air then excess pressure inside it is (4T)/(R) , where T is surface tension of soap and R is the radius of the bubble. Statement-2 : If there is a water drop in air then excess pressure inside it is (2T)/(R) Statement-3 : If there is an air bubble in water then excess pressure inside it is (4T)/(R)

What should be the diameter of a soap bubble in order that the excess pressure inside it is 20 Nm^(-1) . Surface tension = 25 xx 10^(-3) Nm^(-1)

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) p^(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.

The time period of oscillation T of a small drop of liquid under surface tension depends upon the density rho , the radius r and surface tension sigma . Using dimensional analysis show that T prop sqrt((rhor^(3))/(sigma))