1 m aq. Solution of a salt shows elevation in boiling point equal to 3 times of its `K_(b)`. Determine
(i) Freezing point of solution
(ii) Osmotic pressure at `27^(@)C`

Which solution will show maximum elevation in boiling point?

For the same solution the elevation in boiling point has higher values than depression in freezing point.

If for a sucrose, elevation in boiling point is 1.0^(@)C , then what will be the boiling point of NaCl solution for same molal concentration?

A 0.1 molal aqueous solution of a weak acid is 30% ionized. If K_(f) for water is 1.86^(@)C//m , the freezing point of the solution will be.

Equimolal solutions A and B show depression in freezing point in the ratio 2:1 . A remains in the normal state in solution. B will be

The boiling point of 0.1 M KCl solution is ………..than 100^(@)C .

An aqueous solution freezes at -0.2^(@)C . What is the molality of the solution ? Determine also (i) elevation in the boiling point (ii) lowering in vapour pressure at 25^(@)C , given that K_(f)=1.86^(@)C" kg mol"^(-1), K_(b)=0.512^(@)C" kg mol"^(-1) , and vapour pressure of water at 25^(@)C is 23.756 mm.

Consider following figure and answer the questions at the end of it. Figure explains elevation in boiling point when a non-volatile solute is added to a solvent. Variation of vapour pressure with temperature and showing elevation in boiling point. Given that DeltaT_(b) is the elevation in boiling point of the solvent in a solution of molality m then underset(mto0)(Lt)((DeltaT_(b))/(m)) is equal to

Consider following figure and answer the questions at the end of it. Figure explains elevation in boiling point when a non-volatile solute is added to a solvent. Variation of vapour pressure with temperature and showing elevation in boiling point. Elevation in boiling point of an aqueous urea solution is 0.52^(@).(K_(b)=0.52^(@)mol^(-1)kg) . Hence, mole fraction of urea in this solution is: