Equimolar solutions of two non-electroytes in the same solvent have:

Equimolar solutions in the same solvent have-

The vapour pressure of a solution of a non-volatile electrolyte B in a solvent A is 95% of the vapour pressure of the solvent at the same temperature. If the molecular weight of the solvent is 0.3 times, the molecular weight of solute, the weight ratio of the solvent and solute are:

Two solutions of a substance (non-electroyte) are mixed in the following manner 480 mL of 1.5M of first solution with 520 mL or 1.2M of second solution. The molarity of final solution is:

The colligative property of a colloidal sol compared to the solution of non-electrolyte of same cancentration will be

The plot given below shows P – T curves (where P is the pressure and T is the temperature) for two solvents X and Y and isomolal solutions of NaCl in these solvents. NaCl completely dissociates in both the solvents. On addition of equal number of moles of a non-volatile solute S in equal amount (in kg) of these solvents, the elevation of boiling point of solvent X is three times that of solvent Y. Solute S is known to undergo dimerization in these solvents. If the degree of dimerization is 0.7 in solvent Y, the degree of dimerization in solvent X is ______________.

The vapour pressure (VP) of a dilute solution of non-volatile solute is P and the VP of a pure solvent is P^(@) . The lowering of the VP is

How can you justify the observation that the V.P. of solution of a non-volatile solute in a given solvent is less than that of pure solvent. Also state the law concerning the observation.

Calculate the freezing point of a solution of a non-volatile solute in a unknown solvent of molar mass 30g//"mole" having mole fraction of solvent equal to 0.8 . Given that latent heat of fusion of solid solvent =2.7 "kcal mol"^(-1) , freezing point of solvent =27^(@)C and R=2 "cl mol"^(-1)K^(-1) .

At 40^(@)C the vapour pressure of pure liquids, benzene and toluene, are 160 mm Hg and 60 mm Hg respectively. At the same temperature, the vapour pressure of an equimolar solution of the liquids, assuming the ideal solution will be:

Two equimolar solutions have osmotic pressures in the ratio of 2 : 1 at temperatures