At certain Hill-station pure water boils at `99.725^(@)C`. If `K_(b)` for water is `0.513^(@)C kg mol^(-1)`, the boiling point of `0.69m` solution of urea will be:

When 0.6g of urea dissolved in 100g of water, the water will boil at (K_(b) for water = 0.52kJ. mol^(-1) and normal boiling point of water =100^(@)C) :

The molal depression constant for water is 1.86^(@)C . The freezing point of a 0.05-molal solution of a non-electrolyte in water is

The molal boiling point constant of water is 0.573^(@)C kg "mole"^(-1) . When 0.1 mole of glucose is dissolved in 1000g of water, the solution boils under atmospheric pressure at:

A solution of 0.450g of urea (mol.wt 60) in 22.5g of water showed 0.170^(@)C of elevation in boiling point, the molal elevation constant of water:

An aqueous solution of NaCI freezes at -0.186^(@)C . Given that K_(b(H_(2)O)) = 0.512K kg mol^(-1) and K_(f(H_(2)O)) = 1.86K kg mol^(-1) , the elevation in boiling point of this solution is:

Water is added to the solution M such that the mole fraction of water in the solution becomes 0.9 . The boiling point of this solution is