Determination of `Lambda_(m)^(@)` and the degree of dissociation `(alpha)` of a weak electrolyte from Kohlrausch's law/

At a definite temperature, the molar conductivity of a weak electrolytic solution of concentration, C(M) is Lambda_(m) and the value of the molar conductivity at infinite dilution of the same electrolysis solution is Lambda_(m)^(@) . What will be the value of degree of dissociation of the electrolytr C(M) solution?

What is conductance ratio? What is the relation of this to the degree of dissociation of a weak electrolyte?

For the reaction, 2HI(g) iff H_2(g) +I_2 (g) the degree of dissociation ( alpha ) of HI (g) is related to the equilibrium constant, K_p by expression

(b) At a constant temperature, the molar conductivity at infinite dilution of weak electrolyte is "x ohm"^(-1).cm^(2).mol^(-1) . If at the same temperature, the molar conductivity of the same electrolytic solution of a definite concentration is "0.02 x ohm"^(-1)."cm"^(2)."mol"^(-1) , what is the degree of dissociation of the electrolyte in the solution?

Molar conductivity of 0.1 (M) solution of a weak electrolyte is "0.009 ohm"^(-1)."cm"^(-1). Its molar conductivity at infinite dilution is "260 ohm"^(-1)."cm"^(2)."mol"^(-1) . What is the degree of dissociation of the electrolyte in the solution?

Determine the pH of 10^(-8) M HCl acid solution. Show that, degree of dissociation of a weak monobasic acid, alpha=1/(1+10^(pk_a-pH)) , where K_a is the dissociation constant of the weak acid at experimental temperature.

At 318K and 2 atm total pressure the degree of dissociation (alpha) is 28% at the equilibrium condition for the reaction N_(2)O_(4)(g)hArr 2NO_(2)(g) . Calculate K_(p) & K_(c) .

For the reaction N_2O_4 (g) overset(rightarrow)(leftarrow)2NO_2 (g) at equilibrium the degree of dissociation (alpha) is 28% at temperature 318 K and total pressure 2 atm. Calculate the K_P and K_C for the reaction.

Explain how the degree of dissociation of an electrolyte may be determined from the measurement of a colligative property.

Calculating the value of Lambda_(m)^(@) for NH_(4)OH solution requires the value of Lambda_(m)^(@) for the solutions of NH_(4)Cl, NaOH and an electrolyte. Name the electrolyte.