The depth of water at which air bubble of radius 0.4 mm remains in equilibrium is `(T_("water")=72xx10^(-3)N//m)`

Find the depth at which an air bubble of radius 0.7 mm will remain in equilibrium in water . Given surface tension of water = 7.0 xx 10^(-2) N/m.

Calculate the depth of water at which a bubble of air would just float. Density of water =1000 kg^(-3) and density of air = 1.29 kg ^(-3) . Atmospheric pressure = 10^(5) pa.

The excess pressure inside an air bubble of radius 1 mm formed inside water is (S.T=0.072N//)

The work done in splitting a drop of water of 1 mm radius into 10^(6) drops is (S.T. of water =72xx10^(-3)J//m^(2) )

A capillary of internal radius 4 mm , is dipped in water. To how much height, will the water rise in the capillary. ( T_(water) = 70 xx 10^(-3) N//m, g = 10 m//sec^(2), rho_(water) 10^(3) kg//m^(3) , contact angle theta rarr 0 )

A capillary tube of radius 0.25 mm is submerged vertically in water so that 25 mm of its length is outside water. The radius of curvature of the meniscus will be (surface tension of water =75xx10^(-3) N/m)

What should be the pressure inside a small air bubble of 0.1 mm radius situated just below the surface of water? Surface tension of water =72xx10^(-3)N//m and atmospheric pressure =1.013xx10^(5)N//m^(2)

Find the pressure inside an air bubble of radius 1 mm at a depth of 20 m in water. (Assume P _ 0 " " 10 ^5 N//m^ 2 , surface tension of water 0.072 N//m )