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

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 :

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

Water is filled in a capillary tube of radius R. If the surface of water is hemispherical (theta = 0) , then find pressure at a point 'A' which is at h depth below the surface.

If a capillary tube is dipped and the liquid levels inside and outside the tube are same. Then the angle of contact is

A liquid can rise to a height of h in a capillary tube of length l ( l gth ) . The tube filled with the liquid is kept horizontal with its two ends open. Now the tube is kept vertical with the liquid in it. Some liquid flows out. Find the height of the liquid remaining in the tube if the surface tension of the liquid is sigma .

Calculate the height to which the water will rise in a capillary tube of 1.5 mm diameter (surface tension of water =74 times 10^(-3)Nm^(-1) , angle of contact between water and glass =0^(@) ).

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)

A container is partially filled with a liquid of density rho_2 A capillary tube of radius r is vertically inserted in this liquid. Now another liquid of density rho_1(rho_1ltrho_2) is slowly poured in the container to a height h as shown. There is only denser liquid in the capillary tube. The rise of denser liquid in the capillary tube is also h . Assuming zero contact angle, the surface tension of heavier liquid is

Figure shows a capillary tube C dipped in a liquid that wets it. The liquid rises to a point A . If we blow air through the horizontal tube H , what will happen to the liquid column in the capillary tube?