Calculate the `overset(@)Lambda_(m)` for `MgCl_(2)`. The limiting molar conductivities of `Mg^(2+)` and `Cl^(-1)` ions are 106.0 S `cm^(2)" mol"^(-1)` and 76.3 S `cm^(2)"mol"^(-1)`respectively.

Equivalent conductivity at infinite dilution for sodium-potassium oxalate ((COO^(-))_2 Na^(+) K^(+)) will be [given, molar conductivities of oxalate, K^(+) and Na^(+) ions at infinite dilution are 148.2, 50.1, 73.5 S cm^(2) mol^(-2) , respectively ] .

The ionic equivalent conductivities of C_(2)O_(4)^(2-),K^(o+), and Na^(o+) ions are x,y, and z S cm^(2) Eq^(-1) respectively. Calculate wedge_(eq)^(@) of (NaOOC-COOK).

Molar conductivity of a solution is 1.26 xx 10 ^(2) Omega ^(-1) cm ^(2) mol ^(-1). Its solarity is 0.01M. Its specific conductivity will be

1 kg m^(2)s^(-2) =………. g cm^(2) s^(-2)

The ionic molar conductivities of C_(2)O_(4)^(2-),K^(o+) , and Na^(o+) ions are x^('),y^('), and z^(')S cm^(2) mol ^(-1) , respectively. Calculate wedge_(m)^(@) and wedge_(eq)^(@) of (NaOOC-COO) .

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 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 :