The freezing point of a 0.08 molal solution of `NaHSO^(4)` is `-0.372^(@)C`. Calculate the dissociation constant for the reaction.

`K_(f)` for water =`1.86 K m^(-1)`

The freezing point depression of a 0.109M aq. Solution of formic acid is -0.21^(@)C . Calculate the equilibrium constant for the reaction, HCOOH (aq) hArr H^(+)(aq) +HCOO^(Theta)(aq) K_(f) for water = 1.86 kg mol^(-1)K

The depression in the freezing point of a sugar solution was found to be 0.402^(@)C . Calculate the osmotic pressure of the sugar solution at 27^(@)C. (K_(f) = 1.86" K kg mol"^(-1)) .

The freezing point of 0.05 m solution of glucose in water is (K1 = 1.86°C m^(-1) )

The freezing point of 0.08 molal NaHSO_(4) is -0.345^(@)C . Calculate the percentage of HSO_(4)+O ions that transfers a proton to water. Assume 100% ionization of NaHSO_(4) and K_(t) for H_(2)O = 1.86 K molality^(-1) .

The freezing point of a 1.00 m aqueous solution of HF is found to be -1.91^(@)C . The freezing point constant of water, K_(f) , is 1.86 K kg mol^(-1) . The percentage dissociation of HF at this concentration is:-

A solution containing 0.5 g of KCI dissolved in 100 g of water and freezes at -0.24^(@)C . Calculate the degree of dissociation of the salt. ( K_(f) for water = 1.86^(@)C . [Atomic weight K = 39, Cl = 35.5]

0.01 m aqueous solution of K_(3)[Fe(CN)_(6)] freezes at -0.062^(@)C . What is the apparent percentage of dissociation ? ( K_(f) for water = 1.86" K kg mol"^(-1) )

The freezing point depression of 0.1 molal NaCl solution is 0.372 K. What conclusion can you draw about the molecular state of NaCl in water. K_f of water = 1.86 k/m.

The freezing point of a 0.05 molal solution of a non-electrolyte in water is: ( K_(f) = 1.86 "molality"^(-1) )

A 0.5% aqueous solution of KCl was found to freeze at -0.24^(@)C . Calculate the Van,t Hoff factor and degree of dissociation of the solute at this concentration. ( K_(f) for water = 1.86 K kg mol ^(-1) )