The specific conductivity of a solution ...

The specific conductivity of a solution containing `1.0g` of anhydrous `BaCI_(2)` in `200 cm^(3)` of the solution has been found to be `0.0058 S cm^(-1)`. Calculate the molar and equivalent conductivity of the solution. Molecular wt. of `BaCI_(2) = 208`[mu implies `lambda_(m)]`

Similar Questions

Explore conceptually related problems

The specific conductivity of a solution containing 1.0g of anhydrous BaCl_(2) in 200 cm^(3) of the solution has been found to be 0.0058 S cm^(-1) . Calculate the molar and equivalent conductivity of the solution. Molecular wt. of BaCl_(2) = 208 [mu implies lambda_(m)]

The conductivity of a solution containing 1.0 g of anhydrous BaCl_2 in 200 cm^3 of the solution has been found to be 0.0058 S cm^-1 . Calculate the molar conductivity and equivalnet conductivity of the solution.

The specific conductivity of a solution containing 5g of anhydrous BaCl_(2) (mol.wt. = 208) in 1000 cm^(3) of a solution is found to be 0.0058 "ohm"^(-1) cm^(-1) . Calculate the molar and equivalent conductivity of the solution.

Conductivity of a solution containing one gram of anhydrous BaCl_(2) in 200 mL of the solution has been found to be 0.00585 "ohm"^(-) cm^(-) . Calculate the equivalent as well as molar conductance.

The specific conductivity of a solution containing `1.0g` of anhydrous `BaCI_(2)` in `200 cm^(3)` of the solution has been found to be `0.0058 S cm^(-1)`. Calculate the molar and equivalent conductivity of the solution. Molecular wt. of `BaCI_(2) = 208`[mu implies `lambda_(m)]`

Similar Questions

Recommended Questions