The molar conductivity of acetic at infinite dilution is `390.7` and for `0.01 M` acetic acid is `3.9.7 S cm^(2)mol^(-1).` Calculate `(a) alpha ` and `(b) pH` of solution.

Equivalent conductivity of acetic acid at infinite dilution is 39.7 and for 0.1 M acetic acid the equivalent conductance is "5.2 mho.cm"^(2)."gm.equiv."^(-1) . Calculate degree of dissociation, H^(+) ion concentration and dissociation constant of the acid.

The molar ionic conductances at infinite dilution of Mg^(2+) and Cl^(-) are 106.1 and 76.3 ohm^(-1) cm^(2)"mol"^(-1) respectively. The molar conductance of solution of MgCl_(2) at infinite dilution is :

The molar conductance of a 0.01 M solution of acetic acid at 298 K is 16.5 ohm^(-1)cm^(2)"mol"^(-1) . Its specific conductance is :

The molar conductance of CH_(3)COONa , HCl and NaCl at infinite dilution are 91, 426 and 126 S cm^(2)"mol"^(-1) respectively at 25^(@)C . The molar conductance at infinite dilution for CH_(3)COOH would be

The molar conductance at infinite dilution of aluminium sulphate is 858 "ohm"^(-1)"cm"^(2)"mol"^(-1) . Given the molar ionic conductance of sulphate ions as 160"ohm"^(-1)"cm"^(2)"mol"^(-1) , the molar ionic conductance of Al^(3+) ion is :

The conductivity of 0.001028 M acetic acid is 4.95xx10^(-5) S cm^(-1) . Calculate dissociation constant if wedge_(m)^(@) for acetic acid is 390.5 S cm^(2) mol ^(-1) .

The molar conductances of sodium chloride, hydrochloric aciid and sodium acetate at infinite dilution are 126.45, 426.16 and 91.0 ohm^(-1)cm^(2)mol^(-1) at 25^(@)C respectively. Calculate the molar conductance of acetic acid at infinite dilution.