STATEMENT 1 Using koihlrausch's law of independent migration of ions it is possible to calculate `wedge^(@)` for anyelectrolyte form the `lambda^(@)` of individual ions
STATEMENT 2 : Limiting molar molar conductivity of na electrolyte can be repersented as the sum of hte individual contribution of the anion and cation of hte electrolyte
STATEMENT 3: When concentration appraches zero molar conductivity reaches the lowest limit

STATEMENT 1 : The molar conductivity of strong electrolyte decreases with increases in concentration and STATEMENT 2 AT high concentration migration of ion is slow

STATEMENT 1 The molar conductance of weak electrolyte at infinite dilutin is equal to sum of molar conductanced of cation and anion and STATEMENT 2 Kohlraushc 's law is applicable for both strong and weak electrolytes

(a) Apply Kohlrausch law of independent migration of ions, write the expression to determine the limiting molar conductivity of calcium chloride. (b) Given are the conductivity and molar conductivity of NaCI solutions at 298 K at different concentrations : Compare the variation of conductivity and molar conductivity of NaCI solutions on dilution. Give reason. (c) 0.1 M KCI solution offered a resistance of 100 ohms in conductivity cell at 298 K. If the cell constant of the cell is 1.29 cm^(-1) , calculate the molar conductivity of KCI solution.

STATEMENT-1: Molar conductivity increases with decrease in concentration for weak electrolysis. STATEMENT-2: No. of ions increases and no. of ions per unit volume decreases due to dilution.

The variation in Lambda_m with concentration for a strong electrolyte can be represented by the equation, Lambda_m=Lambda_m^@ -AC^(1//2) The value of constant A for a given solvent and temperature depends upon the type of electrolyte i.e., cations and anions produced on dissociation of electrolyte in the solution . Which of the following statements is correct regarding variations of molar conductivity with concentration.

The following curve is obtained when molar conductivity (wedge_(m)) is plotted against the square root of concentration, c^(1//2) for two electrolytes A and B (a) How do you account for the increase in the molar conductivity of the electrolyte A on dilution. (b) As seen from the graph, the value of limiting molar conductivity (wedge_(m)^(0)) for electrolyte B cannot be obtained graphically. How can this value be obtained?1

Consider the statements S1 and S2: S1: Conductivity always increases with decrease in the concentration of electrolyte. S2: Molar conductivity always increases with decrease in the concentration of electrolyte. The correct option among the following is:

Consider the statements S1 and S2. S1: Conductivity always increase with decrease in the concentration of electrolyte S2: Molar conductivity always increases with decrease in the concentration of clectrolyte. The correct option among the following is:

Alkali metals oxide are obtained by combustion of the metals.Although Na normally gives Na_2O_2 ,it will take up further oxygen at elevated pressure and temperature to form NaO_2 .The per and superoxides of the heavier alkalies can also be prepared by passing stoichiometric amounts of oxygen into their solution in liquid ammonia. The different alkali metal oxides can be distinguished by reaction with water.The superoxides reacts with CO_2 and give oxygen gas.The stability of per and superoxides is based upon that larger cation can stablise larger anion, due to larger lattice energy. Alkali metals dissolve in liquid ammonia.Dilute solutions are dark blue in colour but as the concentration increases above 3M, the colour changes to copper bronze and the solution acquires the metallic lusture due to the formation of metal ions clusters.The solutions of alkali metals in liquid ammonia are good conductors of electricity due to the presence of ammoniated cations and ammoniated electrons.However, the conductivity decreases as the concentrations increases, since ammoniated electrons and ammoniated cation associate. KO_2 is used in oxygen cylinders in space and submarines because it :

In a galvanic cell, after running the cell for sometimes, the concentration of the electrolyte is automatically raised to 3 m HCl. Molar conductivity of the 3 m HCl is about "240 S cm"^(2)" mol"^(-1) and limiting molar conductivity of HCl is about "420 cm"^(2)" mol"^(-1) . If K_(b) of water is "0.52 K kg mol"^(-1) , calculate the boiling point of the electrolyte at the end of the experiment.