The vapour pressure of a dilute aqueous solution of glucosse `(C_(6)H_(12)O_(6))` is `750 mm Hg` at `273 K`. Calculate (a) molality and (b) mole fraction of the solute.

The vapour pressure of a dilute aqueous solution of glucose is 700 mm of Hg at 373 K . Calculate the (a) molality and (b) mole fraction of the solute.

The vapour pressure of an aqueous solution of glucose is 750 mm of Hg at 373 K . Calculate molality and mole fraction of solute.

The vapour pressure of a dilute aqueous solution of glucose is 750 mmHg at 373 K. The mole fraction of the solute is

If the vapor pressure of a dilute aqueous solution of glucose is 750 mm of Hg at 373 K , then molality of solute is

Calculate the vapour pressure of an aqueous solution of 1.0 molal glucose solution at 100^(@)C .

The vapour pressure of water at 25^(@)C is 18 mmHg. If 18 g of glucose (C_(6)H_(12)O_(6)) is added to 178.2 g of water at 20^(@)C , the vapour pressure of the resulting solution will be :

At 25^(@)C , the vapour pressure of pure water is 25.0 mm Hg . And that of an aqueous dilute solution of urea is 20 mm Hg . Calculate the molality of the solution.

The vapour pressure of water at 20^(@) C is 17.5 mm Hg. If 18 g of gulucose (C_(6)H_(12)O_(6)) is added to 178.2 g of water at 20^(@) C, the vapour pressure of the resulting solution will be:

The vapour pressure of a pure liquid at 25^(@)C is 100 mm Hg. Calculate the relative lowering of vapour pressure if the mole fraction of solvent in solution is 0.8.

An aqueous solution of sucrose ( C_(12)H_(22)O_(11) ) having a concentration of 34.2gram/ litre has an osmotic pressure of 2.38 atmospheres at 17^(@) C. For an aqueous solution of glucose ( C_(6)H_(12)O_(6) ) to be isotonic with this solution , its concentration should be :