Calculate the molar conductivity of a solution of `MgCl_2` at infinite dilution given that molar conductivities of `lambda^@(Mg^(2+)) = 106.1 s cm^2 mol^(-1) and lambda^@(Cl^(-)) = 76.3 s cm^2 mol^(-1)`

Calculate the molar conductance of a solution of MgCl_2 at infinite dilution, gievn that the molar ionic conductance of lambda^o (Mg^(2+))=126.1S cm^2mol^(-1) and lambda^o (Cl^(-))=56.3 Scm^2mol^(-1) .

Calculate the molar conductance at infinite dilution (lambda^om) of CaCl_2 ,given that molar ionic conductance for lambda^om(Ca^(2+)) 119.5 and Cl- (76.3) S cm^2mol^(-1)

The specific conductance of a saturated solution of AgCl at 298K is found to be 1.386xx10^-6S cm^-1 . Calculate its solubility (lambda^@_(Ag^+)=62.0 S cm^2 mol^-1 and lambda^@_(Cl^-)=76.3 S cm^2 mol^-1 ).

The conductivity of 0.35M NaCl solution at 298K is 0.025 S/cm. Calculate its molar conductivity .

Calculate the limiting molar conductivity of CaSO_4 limiting molar conductivities of calcium and sulphate ions are 119.0 and 106.0 Scm^2 mol^-1 respectively.

The conductivity of 0.001 mol L^-1 solution of CH_3COOH is 3.905xx10^-5 S cm^-1 . Calculate the molar conductivity and degree of dissociation Give that lambda^@(H^+)=349.65 S cm^2 mol^-1 and lambda^@(CH_2COO^-40.9 S cm^2 mol^-1 .

The conductivity of 0.20 MKCl solution at 298 K is 0.0248 S cm^-1 . Calculate its molar conductivity.

The molar conductivity of a 0.5 mol/dm3 solution of AgNO3 with electrolytic conductivity of 5.76 x 10-3 S cm-1 at 298 K is