If a capillary tube of radius 1 mm is immersed in water , the mass of water rising in the capillary tube is M . If the radius tube is doubled , then the mass of water , that rises in the capillary tube will be

A capillary tube of radius R is immersed in water and water rises in it to a height H . Mass of water in the capillary tube is . M If the radius of the tube is doubled, mass of water that will rise in the capillary tube will now be

A capillary tube of radius R is immersed in water and water rises in it to a height H . Mass of water in the capillary tube is . M If the radius of the tube is doubled, mass of water that will rise in the capillary tube will now be

A capillary tube of the radius r is immersed in water and water rise in it to a height H. Mass of water in the capillary tube is m. If the capillary of radius 2r is taken and dipped in water, the mass of water that will rise in the capillary tube will be

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

If 'M' is the mass of water that rises in a capillary tube of radius 'r', then mass of water which will ris in a capillary tube of radius '2r' is :

The rise of a liquid in a capillary tube depends on

A capillary tube of radius r is immersed in water and water rises in to a height h. The mass of water in the capillary tube is 5g. Another capillary tube of radius 2 r is immersed in water. The mass of water that will rise in this tube is

Water rises in a vertical capillary tube up to a length of 10 cm. If the tube is inclined at 45^@ , the length of water risen in the tube will be

When a capillary tube is dipped into a liquid, the liquid neither rises nor falls in the capillary.

The depression of mercury in a capillary tube of radius R_(1) is observed to be equal to the rise of water in another capillary tube of radius R_(2) . If the ratio of surface tension of mercury and water is 7.5 , ratio of their density (p_(Hg))/(p_("water"))=13.6 and their angle of contact are theta_(Hg)=135^(@) and theta_("water")=0^(@) in the respective tubes then R_(1)//R_(2) is :