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 :

The rise of a liquid in a capillary tube is due to :

A liquid of density rho and surface tension sigma rises in a capillary tube of inner raduis R. The angle of contact between the liquid and the glass is theta . The point A lies just below the maniscus in the tube and the point B lies at the outside level of liquid in the beaker as shown in figure. The pressure at A is

The rise of a liquid in a capillary tube depends on

A liquid rises in a capillary tube when the angle of contact is:

The liquid in the capillary tube will rise if the angle of contact is

A capillary tube with inner cross-section in the form of a square of side a is dipped vertically in a liquid of density rho and surface tension rho which wet the surface of capillary tube with angle of contact theta . The approximate height to which liquid will be raised in the tube is : (Neglect the effect of surface tension at the corners of capillary tube)

The correct curve between the height or depression h of liquid in a capillary tube and its radius is

Liquid rises to a height of 2 cm in a capillary tube and the angle of contact between the solid and the liquid is zero. If the tube is depressed more now so that top of capillary is only 1 cm above the liquid, then the apparent angle of contact between the solid and the liquid is

A capillary of radius 0.15mm is dipped in liquid of density 'rho' = 667 kg/m^3. If surface tension of liquid is 1/20 N/m then find height upto which liquid rises in capillary. Angle of contact between liquid and capillary tube is 60^@ . (g=10m/s^2)