`12.2gm` benzoic acid `(M =122)` in `100g H_(2)O` has elevation of boiling point of `0.27^(@)C, K_(b) = 0.54 K` kg/mole. If there is `100%` dimerization the no.of molecules of benzoic acid in associated sate is:

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)

When 20g of naphtholic acid (C_(11)H_(8)O_(2)) is dissolved in 50g of benzene (K_(f) = 1.72 K kg mol^(-1)) a freezing point depression of 2K is observed. The van'f Hoff factor (i) is

When 20g of naphtholic acid (C_(11)H_(8)O_(2)) is dissolved in 50g of benzene (K_(f) = 1.72 K kg mol^(-1)) a freezing point depression of 2K is observed. The van'f Hoff factor (i) is

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:

1.0 molal aqueous solution of an electrolyte X_(3)Y_(2) is 25% ionized. The boiling point of the solution is (K_(b) for H_(2)O = 0.52 K kg//mol) :

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))