The molal boiling point constant for water is`0.513^(@)C kgmol^(-1)`. When `0.1`mole of sugar is dissolved in `200`ml of water , the solution boils under a pressure of one atmosphere at

When 0.1 mole of glucose is dissolved in 10 mole of water, the vapour pressure of water is

The molal cryoscopic for water is 1.86 "K mol"^(-1) . When 3.42 g of sugar ( molar mass = 342) is dissolved in 100 g of water, the solution will freeze at

The solubility of a gas in water at 300 K under a pressure of 100 atmospheres is 4xx10^(-3) "kg L"^(-1) . Therefore, the mass of the gas in kg dissolved in 250 mL of water under a pressure of 250 atmospheres at 300 K is

If K_(f) for water is 1.86^(@)C"mol"^(-1) , a 0.1 m solution of urea in water will have the freezing point of

Boiling point of water at normal atmospheric pressure is

The molar elevation constant for water is 0.52^(@) . The elevation caused in the boiling point of water by dissolving 0.25 mole of a non-volatile solute in 250 g of water will be

The molal elevation constant of water = 0.52 K m^(-1) . The boiling point of 1.0 molal aqueous KCl solution (assuming complete dissociation of KCl ) should be

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

Calculate the molar mass of a substance 1 g of which when dissolved in 100 g of water gave a solution boiling at 100.1^(@)C at a pressure of 1 atm (K_(b) for water = 0.52 K kg mol^(-1))