`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)`:

A 0.2 molal aqueous solution of a weak acid HX is 20% ionized. The freezing point of the solution is (k_(f) = 1.86 K kg "mole"^(-1) for water):

The freezing poing of an aqueous solution of a non-electrolyte is -0.14^(@)C . The molarity of this solution is [K_(f) (H_(2)O) = 1.86 kg mol^(-1)] :

For an aqueous solution freezing point is -0.186^(@)C . The boiling point of the same solution is (K_(f) = 1.86^(@)mol^(-1)kg) and (K_(b) = 0.512 mol^(-1) kg)

The molality of aqueous solution of any solute having mole fraction 0.25 is

Resistance of 0.2 M solution of an electrolyte is 50 Omega . The specific conductance of the solution is 1.3 S m^(-1) . If resistance of the 0.4 M solution of the same electrolyte is 260 Omega , its molar conductivity is .

Resistance of 0.2 M solution of an electrolyte is 50 ohm . The specific conductance of the solution is 1.4 S m^(-1) . The resistance of 0.5 M solution of the same electrolyte is 280 Omega . The molar conductivity of 0.5 M solution of the electrolyte in S m^(2) mol^(-1) id

Calculate the molality of 1 L solution of 93% H_(2)SO_(4) (Weight/volume) The density of the solution is 1.84 g .

A 5.2 molal aqueous of methyl alcohol, CH_(3)OH , is supplied. What is the molefraction of methyl alcohol in the solution ?

In a 0.2 molal aqueous solution of a weak acid HX the degree of ionization is 0.3 . Taking k_(f) for water as 1.85 the freezing point of the solution will be nearest to-

30mL of CH_(3)OH (d = 0.780 g cm^(-3)) and 70 mL of H_(2)O (d = 0.9984 g cm^(-3)) are mixed at 25^(@)C to form a solution of density 0.9575 g cm^(-3) . Calculate the freezing point of the solution. K_(f)(H_(2)O) is 1.86 kg mol^(-1)K . Also calculate its molarity.