The limiting equivalent conductivity of `NaCl, KCl` and `KBr` are `126.5,150.0` and `151.5 S cm^(2) eq^(-1)` , respectively. The limiting equivalent ionic conductance for `Br^(-)` is `78 S cm^(2) eq^(-1)`. The limiting equivalent ionic conductance for `Na^(+)` ions would be `:`

A^@_m for NaCl, HC1 and NaAc are 126.4, 425.9 and 91.0 S cm^2 mol_-1 respectively. Calculate A^@ for HAc.

The limiting molar condcutance of sodium chloride, potassium chloride and potassium bromide are 126.45, 149.86 and 151.92 ohm^-1 cm^2 mol^-1 respectively. Calculate the limiting molar ionic conductance of Na^+ given that limiting molar ionic conductance of Br^- ion is 76.34 ohm^-1 cm^2 mol^-1 .

The equivalent conductance of Ba^(2+) and Cl^(c-) are 63.5ohm^(-1) cm^(2) eq^(-1) and 76 ohm^(-1) cm^(2)eq^(-1) , respectively, at infinite dilution . The equivalent conductance ( in oh^(-1) cm^(2)) of BaCl_(2) at infinite dilution will be

If limiting molar conductivity of Ca^(2+) and Cl^(-) are 119.0 and 76.3 S cm^2 mol^(-1) , then the value of limiting molar conductivity of CaCl_2 will be :

The lamda^(@) values of NaCl and NanO_(3) are 126.5 and 121.6S" "cm^(2)mol^(-1) respectively. The lamda^(@) value of NO_(3)^(-) ion is 76.3 S cm^(2)mol^(-1) calculate lamda^(@)(Cl^(-)) .

The lamda^(@) values of KNO_(3) and LiNO_(3) are 145.0 and 110.1 S cm^(2)mol^(-1) respectively. The lamda^(@) value of K^(+) ion is 73.5"S "cm^(2)mol^(-1) . Calculate lamda^(@)(Li^(+)) .

The lamda^(@) values of KCl and KNO_(3) are 149.9 and 144.9 S cm^(2)mol^(-1) respectively. Also lamda^(@) for Cl^(-) is 71.44 S cm^(2)mol^(-1) .The lamda^(@) value of NO_(3)^(-) ion.

The conductivity of a saturated solution of AgBr at 25^@C is 8.5xx10^-7 S cm^-1 . If the limiting molar ionic conductance of Ag^+ and Br^- ions are 62 and 78 S cm^2 mol^-1 , then calculate the solubility product of AgBr.