molar conductivity`(bidwedge_m)` is defined as conducting power of the ions producedd by 1 mole of an electrolyte in a solution. `bidwedge_m=K/C` Where k is conductivity `(Scm^2mol^(-1))` and C is molar concentration `(in mol//cm^3)`
The molar conductivity of 0.04 M solution of `MgCl_2` is 200 `Scm^3mol^(-1)` at 298 k. A cell with electrodes that are 2.0`cm^2` in surface area and 0.50cm apart is filled with `MgCl_2` solution.
Conductance of `MgCl_2` solution is :

molar conductivity (bidwedge_m) is defined as conducting power of the ions producedd by 1 mole of an electrolyte in a solution. bidwedge_m=K/C Where k is conductivity (Scm^2mol^(-1)) and C is molar concentration (in mol//cm^3) The molar conductivity of 0.04 M solution of MgCl_2 is 200 Scm^3mol^(-1) at 298 k. A cell with electrodes that are 2.0 cm^2 in surface area and 0.50cm apart is filled with MgCl_2 solution How much current will flow when the potential difference between the two electrodes is 5.0V?

The conductivity of 0.20M solution of KCl at 298K is 0.0248 S cm^(-1) . Calculate its molar conductivity.

The conductivity of 0.20 M solution of KCl at 298 K is 0.0248 S cm^(-1) . Calculate its molar conductivity.

The conductivity of 0.35M solution of KCl at 300K is 0.0275 S cm^(-1) . Calculate molar conductivity

The conductivity of 0.20 M KCl solution at 298 K is 0.025 S cm^(-1) . Calculate its molar conductivity .