What weight of non-volatile solute (urea) `NH_(2) CO NH_(2)` needs to be dissolved in 100 g of water in order to decrease the vapour pressure of water by `25%`. What will be the molality of solution?

The mass of a non-volatile solute of molar mass 40 g mol^(-1) that should be dissolved in 114 g of octane to lower its vapour pressure by 20% , is

What is the vapour pressure of pure water at 100^(@)C temperature ?

The mass of glucose that should be dissolved in 100 g of water in order to produce same lowering of vapour pressure as is produced by dissolving 1 g of urea in 50 g of water is

Vapour pressure of pure water at 298 K is 23.8 mm Hg. 50 g of urea (NH_2CONH_2) is dissolved in 850 g of water. Calculate the vapour pressure of water for the solution and its relative lowering.

100 g of water is added to a 100 cc solution of sugar of density 1.5 g/cc. what is the density of the new mixture?

6.0 g of urea (molecular weight=60) was dissolved in 9.9 moles of water. If the vapour pressure of pure water is P^@ , the vapour pressure of solution is :

y g of non-volatile solute of molar mass M is dissolved in 250 g benzene. If K_b is molal elevation constant, the value of DeltaT is given by

The vapour pressure of water at room temperature is lowered by 5% by dissolving a solute in it, then the approximate molality of solution is

18 g glucose (C_6H_12O_6) is added to 178.2 g water. The vapor pressure of water (in torr) for this aqueous solution is.

20 g of a solid solute is dissolved in 180 g of water. At 100^(@)C the vapour pressure of the solution becomes 740 mmHg. Calculate relative molecular mass of the solute. (No association/dissociation of the solute takes place )