Expression for the height of capillary rise between two parallel plates dipping liquid of density `sigma` separated by a distance d. The surface tension of the liquid is T. [Take angle of contact to be zero]

Derive an expression for the height of capillary rise between two parrallel plates dipping in a liquid of density sigma separated by a distance d . The surface tension of the liquid is T .

Two parallel glass plates separated by a small distance x ar dipped partly in a liquid of density ' d keeping them vertical .The surface tension of the liquid is T and angle of contact is theta . What is the rise of the liquid between the plates due to capillarity ?

Two parallel glass plates are dipped partly in the liquid of density d keeping them vertical. If the distance between the plates is x surface tension for the liquid is T and angle of contact theta , then rise of liquid between the plates due to capillary will be

What is the height to which a liquid rises between two long parallel plates, a distance d apart ? (Surface tension of liquid is T and density is rho )

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

A square wire frame of L is dipped in a liquid, on taking out a membrane is formed. If the surface tension of liquid is T, force acting on the frame will be

A capillary tube of radius r is immersed in water and water rises to a height of h mass of water in the capillary tube is 5xx10^(-3) kg the same capillary tube is now immersed in a liquid whose surface tension in sqrt(2) times the surface tension of water. The angle of contact between the capillary tu8be and this liquid is 45^(@) the mass of liquid which rises into the capillary tube now is (in kg)

The force due to surface tension in a capillary tube supports a liquid column of weight 48 pi mu N . If the surface tension of the liquid. is 0.04 N/m and the angle of contact is 0^(@) , the diameter of the capillary tube is

It is said that a liquid rises or is depressed in a capillary due to the surface tension. If a liquid neither rises nor depresses in a capillary, can we conclude that the surface tension of the liquid is zero ?