Weight of solute (M. wt 60) that is required to dissolve in 180 g water to redure the vapour pressure to `4//5th` of pure water is `50x g . X ` is

The weight of urea to be dissolved in 100 g. of water to decrease the vapour pressure of water by 5% is

6 g of urea is dissolved in 90g of boiling water. The vapour pressure of the solution is

The weight in grams of a non-volatile solute (mol.wt.60) to be dissolved in 90 g of water to produce a relative lowering of vapour pressure of 0.02 is

18 g of glucose is dissolved in 90 g of water. The relative lowering of vapour pressure of the solution is equal to

Moles of K_(2)SO_(4) to be dissolved in 12 mol water to lowest its vapour pressure by 10 mm of Hg at a temperature at which vapour pressure of pure water is 50 mm is :

The weight in grams of a non-volatile solute (mol.wt.60) to be dissolved in 90g of water to produce a relative lowering of vapour pressure of 0.02 is

How many grams of H_(2)SO_(4) required to be dissolved in 250g of water to prepare decimolal solution?

What weigth of a non-volatile solute (molar mass 40 g) should be dissolved in 114 g of octance to reduce its vapour pressure by 20%.

Vapour pressure of pure water at 298 K is 23.8 mm Hg. 50g urea (NH_(2)CONH_(2)) is dissolved in 850 g of water. Calculate the vapour pressure of water for this solution and its relative lowering. Consider Raoult's law and formula for relative lowering in vapour pressure, (P_(A)^(0)-P_(s))/(P_(A)^(0))=(n_(B))/(n_(A))=(W_(B))/(M_(B))xx(M_(A))/(W_(A)) Where, (P_(A)^(0)-P_(s))/(P_(A)^(0)) is called relative lowering in vapour pressure.