To find the resistance offered by the conductivity cell, we first need to calculate the conductivity (
κ ) of the solution using the provided molar conductivity
∧ and concentration
c.
Molar conductivity
∧ is the conductivity per mole of solution and is related to the overall conductivity
k by the equation:
κ=Λ⋅cWhere:
K is the conductivity in
ohm‌cm−1Λ is the molar conductivity in
ohm‌‌−1‌cm2‌mol−1c is the concentration in moles per
cm3Given:
‌Λ=194.5ohm−1cm2mol−1‌c=0.05M=0.05‌mol‌/‌L=0.05‌mol∕1000cm3=0.00005‌mol∕cm3
Calculating
k :
K=194.5ohm−1cm2mol−1×0.00005‌mol‌/‌cm3=0.009725ohm−1‌cm
Next, we use the cell constant (G) to relate the resistance (R) of the cell to its conductivity. The cell constant is defined as the inverse of the distance between the electrodes divided by their area:
G=‌Where:
I is the distance between the electrodes in
cmA is the area of the electrodes in
cm2Given:
‌l=1.0‌cm‌A=3.0cm2Calculating
G :
G=‌=0.3333cm−1The resistance
R can then be calculated using the equation:
R‌=‌Therefore, the resistance offered by the conductivity cell is 34.27 ohms.
The correct option is
D(34.27 ohms).