A saturated solution in `AgX(K_(sp)=3xx10^(-12))` and `AgY(K_(sp)=10^(-12))` has conductivity `0.4xx10^(-6)Omega^(-1)cm^(-1)`.
Given: Limiting molar conductivity of `Ag^+=60Omega^(-1)cm^2mol^(-1)`
Limiting molar conductivity of `X^(-)=90Omega^(-1)cm^2mol^(-1)`
The conductivity of `Y^(-)` is (in `Omega^(-1)cm^(-1)`):

A saturated solution in AgA (K_(sp)=3xx10^(-14)) and AgB (K_(sp)=1xx10^(-14)) has conductivity of 375xx10^(-10) S cm^(-1) and limiting molar conductivity of Ag^(+) and A^(-) are 60S cm^(2) "mol"^(-1) and 80 S cm^(2) "mol"^(-1) respectively , then what will be the limiting molar conductivity of B^(-) (in S cm^(2) "mol"^(-1) )?

A saturated solution in AgA (K_(sp)=3xx10^(-14)) and AgB (K_(sp)=1xx10^(-14)) has conductivity of 375xx10^(-10) S cm^(-1) and limiting molar conductivity of Ag^(+) and A^(-) are 60S cm^(2) "mol"^(-1) and 80 S cm^(2) "mol"^(-1) respectively , then what will be the limiting molar conductivity of B^(-) (in S cm^(2) "mol"^(-1) )?

What must be the concentration of a solution of silver nitrate to have the molar conductivity of 121.4 Omega ^(-1) cm^2 mol^(-1) and the conductivity of 2.428 xx10^(-3) Omega^(-1)cm^(-1) at 25 ^@C ?

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

The Conductivity of 0.02M Ag NO_(3) at 25^(@)C is 2.428 xx 10^(-3) Omega^(-1) cm^(-1) . What is its molar conductivity?