[" The molar conductivity of KCI solutions at different concentrat "],[298K" are given below: "],[c/molL^(-1),Lambda_(m)/Scm^(2)mol^(-1)],[0.000309,148.29],[0.000521,147.81],[0.000989,147.09]

The molar conductivity of KCl solutions at different concentration at 298K are given below : {:(C//"mol L"^(-1),wedge_(m)//S cm^(2)"mol"^(-1)),(0.000198,148.61),(0.000309,148.29),(0.000521,147.81),(0.000987,143.09):} Show that a plot between wedge_(m) and C^(1//2) is a straight line. Determine the values of wedge_(m)^(0) and wedge for KCl.

The molar conductivity of KCl solution at different concentrations at 298 K is given below : {:(c or M (mol L^(-1)),wedge_(m)(Scm^(2)mol^(-1))),(0.000198,148.61),(0.000309,148.29),(0.000521,147.81),(0.000989,147.09):} Show that a plot between wedge_(m) and sqrt(c) is a straight line. Determine the value of wedge_(m)^(@) and A for KCl .

The molar conductivity of KCl solution at different concentrations at 298 K is given below : {:(c or M (mol L^(-1)),wedge_(m)(Scm^(2)mol^(-1))),(0.000198,148.61),(0.000309,148.29),(0.000521,147.81),(0.000989,147.09):} Show that a plot between wedge_(m) and sqrt(c) is a straight line. Determine the value of wedge_(m)^(@) and A for KCl .

The molar conductance of NaCl solution at different concentration at 298K are given below : {:(C(mol L^(-1)),wedge_(m)(S cm^(2)mol^(-1))),(0.001,123.7),(0.010,118.5),(0.020,115.75),(0.050,111.06):} Plot a graph between wedge_(m) and C^(1//2) and determine the value of wedge^(@)m from it.

Molar conductivity of 0.15 M solution of KCI at 298 K, if its conductivity is 0.0152 S cm^(-1) will be

Molar conductivity of 0.15 M solution of KCI at 298 K, if its conductivity is 0.0152 S cm^(-1) will be