A solution containing 6 gm of a solute dissolved in 250 ml of water gave an osmotic pressure of 4.5 atmosphere at `27^(@)C`. Calculate the boiling point of the solution. The molal elevation constant for water is 0.52

A solution containing 6 g of a solute dissolved in 250 cm^(3) of water gave an osmotic pressure of 4.5 atm at 27^(@)C . Calculate the boiling point of the solution.The molal elevation constant for water is 0.52^@ C per 1000 g.

10g of an organic substance when dissolved in two litres of water gave an osmotic pressure of 0.59 atm, at 7^(@)C . Calculate the molecular weight of the substance.

0.6g of a solute is dissolved in 0.1 litre of a solvent which develops an osmotic pressure of 1.23 at m at 27^(@)C .The molecular mass of the substance is

A solution containing 4 g of a non-volatile organic solute per 100 mL was found to have an osmotic pressure equal to 500 cm of mercury at 27^(@)C . The molecular weight of solute is

Calculated the molality of a sulphuric acid solution in which the mole fraction of water is 0.85.

Osmotic pressure of a sugar solution at 24^(@)C is 2.5 atm. The concentration of the solution in gm mole per litre is :

A 10 g mixture of glucose and urea present in 250 mL solution shows the osomotic pressure of 7.4 atm at 27^(@)C . Calculate % composition of mixture.

A solution containing 2.5 g of a non-volatile solute in 100 gm of benzene boiled at a temperature 0.42K higher than at the pure solvent boiled. What is the molecular weight of the solute? The molal elevation constant of benzene is "2.67 K kg mol"^(-1) .

By dissolving 13.6 g of a substance in 20 g of water, the freezing point decreased by 3.7^(@)C . Calculate the molecular mass of the substance. (Molal depression constant for water = 1.863K kg mol^(-1))