Two capillary tubes of radii 0.3cm and 0.6 cm are dipped in the same liquid. The ratio of heights through which the liquid will rise in the tubes is

Select and write the correct answer:- Two capillary tubes of radii 0.1 cm and 0.2 cm are dipped in the same liquid. The ratio of heights through which the liquid will rise in the tubes is

Two capillary tubes of radii 0.2 cm and 0.4 cm are dipped in the same liquid. The ratio of heights through which liquid will rise in the tubes

The height to which a liquid will rise in a capillary tube is

Two tubes of same material but of different radii are dipped in a liquid . The height to which a liquid rises in one tube is 2.2 cm and in the other is 6.6 cm . The ratio of their radii is

When two capillary tubes of different diameters are dipped vertically in a liquid , the rise of the liquid in the capillary tube

The radius of the bore of a capillary tube is r and the angle of contact of the liquid is theta . When the tube is dipped in the liquid , the radius of curvature of the meniscus of liquid rising in the tube is

A glass capillary tube of radius r is placed vertically touching the surface of water. The water rises to height h in capillary tube. If now the tube is dipped into water till only h/2 length of it is outside the water surface the , radius of curvature of the meniscus of water in capillary tube will be,

Two capillaries A and B are dipped in water and held vertical . The diameter of A is twice that of B . The ratio of the heights to which water rises in A and B is

A capillary tube 0.14mm in diameter has its lower end immersed in a liquid of surface tension 0.054 N//m . If the density of a liquid is 860 kg//m^3 , find the height to which the liquid rises in the tube.(Angle of contract of liquid with glass is 28^@ and g=9.8 m//s^2 ).

A capillary tube of radius 0.02 cm is dipped vertically in a beaker containing mercury. The level of mercury in the tube with respect to the mercury level in the beaker will be (Given density of mercury 13.5 g//cc, Surface tension 540 dyne/cm and the angle of contact 135^@ )