The value of `K_(f)` for water is `1.86^(@)`, calculated from glucose solution. The value of `K_(f)` for water calculated for `NaCl` solution will be

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

In a 0.2 molal aqueous solution of a weal acid, HX, the degree of dissociation is 0.3 . Taking K_(f) for water as 1.85, the freezing point of the solution will be nearest to

A solution of urea in water has boiling point of 100.15^(@)C . Calculate the freezing point of the same solution if K_(f) and K_(b) for water are 1.87 K kg mol^(-1) and 0.52 K kg mol^(-1) , respectively.

What do you understand by the term that K_(f) for water is 1.86 K kg mol^(-1) ?

1F of electricity is passed through 10 L of a solution of aqueous solution of NaCl . Calculate the pH of the solution.

A solution of a non-volatile solute in water freezes at -0.30^(@)C . The vapour pressure of pure water at 298 K is 23.51 mm Hg and K_(f) for water is 1.86 degree//molal . Calculate the vapour pressure of this solution at 298 K .

A solution of non-volite solute in water freezes at -0.30^(@)C .The vapour pressure of pure water at 298 K is 23.51 mm Hg .and K_(f) for water is 1.86 degree per molal. Calculate the vapour pressure of this solution at 298 K .

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)