The equivalent conductivity of a solution containing 2.45 g of `CuSO_(4)` per litre, is `91.0 Omega^(-1) cm^(2) eq^(-1)`. Its conductivity would be

The molar conductivity of 0.05 M BaCl_(2) solution at 25^(@)C is 223 Omega^(-1)"cm"^(2) mol^(-1) . What is its conductivity?

Molar conductivity of a solutions is 1.26xx10^(2) Omega^(-1)cm^(2) "mol"^(-1) its molarity is 0.01. its specific conductivity will be

The equivalent conductance of a 0.2 n solution of an electrolyte was found to be 200Omega^(-1) cm^(2)eq^(-1) . The cell constant of the cell is 2 cm^(-1) . The resistance of the solution is

The equivalent conductivity of H_(2)SO_(4) at infinite dilution is 384 Omega^(-1) cm^(2) eq^(-1) . If 49g H_(2)SO_(4) per litre is present in solution and specific resistance is 18.4 Omega then calculate the degree of dissociation.

The conductivity of saturated solution of Ba_(3) (PO_(4))_(2) is 1.2 xx 10^(-5) Omega^(-1) cm^(-1) . The limiting equivalent conductivities of BaaCl_(2), K_(3)PO_(4) and KCl are 160, 140 and 100 Omega^(-1) cm^(2)eq^(-1) , respectively. The solubility product of Ba_(3)(PO_(4))_(2) is

The molar conductivity of 0.05 M of solution of an electrolyte is 200 Omega^(-1) cm^2 . The resistance offered by a conductivity cell with cell constant (1//3) cm^(-1) would be about .

If the specific conductane of 1 M H_(2)SO_(4) solution is 26xx10^(2)S cm^(2) , then the equivalent conductivity would be