The resistance of 0.01 M NaCl solution at 25°C is 200 ohm.The cell constant of the conductivity cell used is unity. Calculate the molar conductivity of the solution.

(a) What are the two classifications of batteries ? What is the difference between them ? (b) The resistanc of 0.01 M NaCl solution at 25^(@)C is 200Omega. The cell constant of the conductivity cell is unity. Calculate the molar conductivity of the solution.

The resistance of 0.01 N solution at 25^(@)C is 200 ohm. Cell constant of the conductivity cell is unity. Calculate the equivalent conductance of the solution.

At 25^(@)C , the resistance of 0.01 N NaCl solution is 200 ohm . If cell constant of the conductivity cell is unity, then the equivalent conductance of the solution is:

The resistance of 0. 01 N NaCl solution at 25^@C is 200 Omega . Cell constant of conductivity cell is 1 cm^(-1) . The equivalent conductnance is .

The specific conductivity of 0.02 M KCl solution at 25^(@)C is 2.768xx10^(-3) ohm^(-1) cm^(-1) . The resistance of this solution at 25^(@)C when measured with a particular cell was 250.2 ohm. The resistance of 0.01 M CuSO_(4) solution at 25^(@)C measured with the same cell was 8331 ohm. Calculate the molar conductivity of the copper sulphate solution.

0.05 M NaOH solution offered a resistance of 3.1*6Omega in a conductivity cell at 298 K. If the cell constant of the cell si 0*367cm^(-1), calculate the molar conductivity of NaOH solution.

(a) Apply Kohlrausch law of independent migration of ions, write the expression to determine the limiting molar conductivity of calcium chloride. (b) Given are the conductivity and molar conductivity of NaCI solutions at 298 K at different concentrations : Compare the variation of conductivity and molar conductivity of NaCI solutions on dilution. Give reason. (c) 0.1 M KCI solution offered a resistance of 100 ohms in conductivity cell at 298 K. If the cell constant of the cell is 1.29 cm^(-1) , calculate the molar conductivity of KCI solution.