The specific conductivity of N/10KCl solution at `20^(@)C` is 0.0212 `ohm^(-1) cm^(-1)` and the resistance of the cell containing this solution at `20^(@)C` is 55 ohm. The cell constant is

The specific conductivity of N/10 KCl solution at 20^(@)C is 0.0212 ohm^(-1) cm^(-1) and the resistance of the cell containing this solution at 20^(@)C is 55 ohm. The cell constant is :

The specific conductance of a 0.1 N KCl solution at 23^(@)C is 0.012 "ohm"^(-1)"cm"^(-1) . The resistance of the cell containing the solution at the same temperature was found to be 55 ohm. The cell constant will be

The specific conductance of a 0.1 N KCI solution at 25^@ C is 0.015 ohm^ (-1) cm^(-1) . The resistances of the cell containing the solution at the same temperature was found to be 60 Omega . The cell constant (in cm^(-1)) will be

The specific conductance of a N//10 KCI solution at 18^(@)C is 1.12 xx 10^(-2) mho cm^(-1) . The resistance of the solution contained in the cell is found to be 65 ohms. Calculate the cell constant.

The specific conductivity of 0.5N solution is 0.01287 ohm^(-1) cm^(-1) . What would be its equivalent conductance?

The conductivity of 0.02 N solution of a cell of KCl at 25^@C" is "2.765 xx 10^(-3) Scm^(-1) . If the resistance of a cell containing this solution is 4000 ohm, what will be the cell constant?

The specific conductivity of 0.1 N KCl solution is 0.0129Omega^(-1)cm ^(-1) . The cell constant of the cell is 0.01 cm^(-1) then conductance will be:

The conductivity of 0*2M " KCl solution is " 3 Xx 10^(-2) ohm^(-1) cm^(-1) . Calculate its molar conductance.

At 25°C the specific conductance of a 1N solution of KCl is 0.002765 mho. The resistance of cell is 400 Omega . The cell constant is: