Calculate the boiling point of solution when 2 g of `Na_(2)SO_(4) (M = 142 g mol^(-1)`) was dissolved in 50g of water , assuming `Na_(2)SO_(4)` undergoes complete ionization . (`k_(b)` for water `= 0.52 K kg mol^(-1)`).

Calculate the boiling point of solution when 4g of Mg SO_(4) (M=120g "mol"^(-1)) was dissolved in 100g of water, assuming MgSO_(4) undergoes complete ionization (K_(b) " for water " = 0.52 K " kg mol"^(-1))

(a) Calculate the freezing point of solution when 1.9 g of MgCl_(2) (M = 95 g Mol^(-1) ) was dissolved in 50g of water, assuming MgCl_(2) undergoes complete ionization. ( K_(f) for water = 1.86 K kg mol^(-1) ). (b) (i) Out of 1 M glucose and 2 M glucose, which one has a higher boiling point and why? (ii) What happens when the external pressure applied becomes more than the osmotic pressure of solution?

Calculate the freezing point of a solution when 3 g of CaCI_(2) (M=111 g mol^(-1)) was dissolved in 100g of water assuming that CaCI_(2) undergoes complete ionisation (K_(f) "for water"=1.86 K kg mol^(-1)) .

When 25 g of Na_(2)SO_(4) is dissolved in 10^(3) Kg of solution, its concentration will be

Calculate the freezing point of a solution containing 0.5 g KCl (Molar mass = 74.5 g/mol) dissolved in 100 g water, assuming KCl to be 92% ionized. K_(f) of water = 1.86 K kg/mol.

Calculate the freezing point of a solution containing 60 g glucose (Molar mass = 180 g mol^(-1) ) in 250 g of water . ( K_(f) of water = 1.86 K kg mol^(-1) )