A liquid drop of density `rho` , radius `r`, and surface tension `sigma` oscillates with time period `T` . Which of the following expressions for `T^(2)` is correct?

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)?

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))

Frequency is the function of density (rho) , length (a) and surface tension (T) . Then its value is

A liquid of density rho and surface tension sigma rises in a capillary tube of diameter d. Angle of contact between the tube and liquid is zero. The weight of the liquid in the capillary tube is:

A liquid of density rho and surface tension sigma rises in a capillary tube of diameter d . Angle of contact between the tube and liquid is zero. In the above problem, the increase in gravitational potential energy of the liquid due to rise in the capillary is :

If the time period t of the oscillation of a drop of liquid of density d, radius r, vibrating under surface tension s is given by the formula t=sqrt(r^(2b)s^(c)d^(a//2)) . It is observed that the time period is directly proportional to sqrt((d)/(s)) . The value of b should therefore be :

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

A needle of length l and density rho will float on a liquid of surface tension sigma if its radius r is less than or equal to:

A sphere of radius r is dropped in a liquid from its surface. Which of the following graphs is/are correct?

Calculate the pressure inside a small air bubble of radus r situated at a depth h below the free surface of liquids of densities rho_(1) and rho_(2) and surface tennsions T_(1) and T_(2) . The thickness of the first and second liquids are h_(1) and h_(2) respectively. Take atmosphere pressure =P_(0) .