`12g` of a nonvolatile solute dissolved in `108g` of water produces the relative lowering of vapour pressure of `0.1`. The molecular mass of the solute is

The vapor pressure of acetone at 20^(@)C is 185 torr. When 1.2 g of a non-volatile solute was dissolved in 100 g of acetone at 20^(@)C , it vapour pressure was 183 torr. The molar mass (g mol^(-1)) of solute is:

Vapour pressure of a solvent containing nonvolatile solute is:

For a silute solution conatining 2.5 g of a non-volatile non-electrolyte solute in 100g of water, the elevation in boiling point at 1 atm pressure is 2^(@)C . Assuming concentration of solute is much lower than the concentration (take K_(b) = 0.76 K kg mol^(-1))

A solution containing 30g of a nonvolatile solute in exactly 90g water has a vapour pressure of 21.85 mm Hg at 25^(@)C . Further 18g of water is then added to the solution. The resulting solution has vapour pressure of 22.18 mm Hg at 25^(@)C . calculate (a) molar mass of the solute, and (b) vapour pressure of water at 25^(@)C .

What is the freezing point of solution containing 3g of a non-volatile solute in 20g of water. Freezing point of pure water is 273K, K_(f) of water = 1.86 Kkg/mol. Molar mass of solute is 300 g/mol. T^(@)-T=K_(f)m

The addition of 3g of a substance to 100g C CI_(4)(M = 154 g mol^(-1)) raises the boiling point of C CI_(4) by 0.60^(@)C if K_(b)(C CI_(4)) is 5K mol^(-1) kg , calculate (a) the freezing point depression (b) the relative lowering of vapour pressure (c) the osmotic pressure at 298K and (d) the molar mass of the substance. Given: K_(f) (C CI_(4)) = 31.8 K kg mol^(-1) and rho (solution) = 1.64 g cm^(-3)