The molar conductivities `Lambda_(NaOAc)^@` and `Lambda_(HCI)^@` at infinite dilution is watter at `25^@C` are `91.0` and `426.2 S cm^@ //`mol respectively. To calculate `Lambda_(HOAc,)^2` the additional value required is:

The equivalenet conductivites of acetic acid at 298K at the concentration of 0.1M and 0.001M are 5.20 and 49.2S cm^(2) eq^(-1) respectively. Calculate the degree of dissociation of acetic acid at the these concentrations. Given that, lambda^(prop) (H^(+)) and lambda^(prop) (CH_(3)COO^(-)) are 349.8 and 40.9 ohm^(-1) cm^(2) mol^(-1) respectively.

The equivalent conductance of NaCl at concentration C and at infinite dilution are lambda_(C) and lambda_(oo) , respectively. The correct relationship between lambda_(C) and lambda_(oo) is given as (where, the constant B is positive)

The limiting molar conductivities A^(@) for NaCl,KBr nd KCl are 126,152 and 150 S cm^(2) "mol"^(-1) respectively. The A^(@) for NaBr is:

The dissociation constant of n-butyric acid is 1.6 xx 10^(-5) and the molar conductivity at infinite dilution is 380 xx 10^(-4) Sm^(2) mol^(-1) . The specific conductance of the 0.01M acid solution is

At infinite dilution the molar conductance of Al^(+3) and SO_(4)^(-2) ion are 189 and 160 Omega^(-1) cm^(2) "mole"^(-1) respectively. Calculate the equivalent and molar conductivity at infinite dilute of Al_(2)(SO_(4))_(3) .