The equivalent conductivity of `0.1 M` weak acid is `100` times less than that at infinite dilution. The degree of dissociation of weak electrolyte at `0.1 M` is.

At infinite dilution, the percentage dissociation of both weak acid and weak base is:

The specific conductance of a0.5 N solution of an electrolyte at 25^@C is 0.00045 Scm^(-1) . The equivalent conductance of this electrolyte at infinite dilution is 300 S cm^2eq^(-1) . The degree of dissociation of the electrolyte is

On diluting aqueous solution of weak electrolyte to 100 times

The equivalent conductance of M//32 solution of a weak monobasic acid is 8.0 and at infinite dilution is 400 . The dissociation constant of this acid is :

The equivalent conductance of (M)/(20) solution of a weak monobasic acid is 10 mhos cm^(2) and at infinite dilution is 200 mhos cm^(2) . The dissociation consant of this acid is :-

At 0.04 M concentration the molar conductivity of a solution of a electrolyte is 5000Omega^(-1)cm^(2)mol^(-1) while at 0.01 M concentration the value is 5100Omega^(-1)cm^(2)mol^(-1) making necessary assumption (taking it as strong electrolyte) find the molar conductivity at infinite dilution and also determine the degree of dissociation of strong electrolyte at 0.04M.

The increase in equivalent conductivity of a weak electrolyte with dilution is due to :

HA is a weak acid. The pH of 0.1 M HA solution is 2. What is the degree of dissociation (alpha) of HA ?

Equivalent conductane of 0.1 M HA (weak acid) solution is 10 S cm^(2) "equivalent"^(-1) and that at infinite dilution is 200 S cm^(2) " equivalent"^(-1) Hence pH of HA solution is

Assertion:Kohlrausch law helps to find the molar conductivity of weak electrolyte at infinite dilution. Reason:Molar conductivity of a weak electrolyte at infinite dilution cannot be determined experimentally.