91Ó°ÊÓ

• Thickness of mica sheet,$\mathrm{a}=0.10\mathrm{mm}$
• Thickness of glass sheet,$\mathrm{a}=2.0\mathrm{mm}$
• Thickness of slab of paraffin,$\mathrm{a}=1.0\mathrm{cm}$
• Dielectric constant of mica,$\mathrm{κ}=5.4$
• Dielectric constant of glass,$\mathrm{κ}=7.0$
• Dielectric constant of paraffin,$\mathrm{κ}=2.0$

A capacitor is a device that can store a charge. The capacity to store the charge is called capacitance. The capacitance can be written in terms of permittivity of the free space, the dielectric medium between the two plates, area of the cross-section of two plates, and the separation between the two plates.

We use the formula of the capacitance of the parallel plate capacitor to calculate the capacitance of the capacitor.

Formulae:

The capacitance between the capacitor plates,$C=\frac{{\mathrm{Î\mu }}_{0}kA}{d}$ …(¾±)

Here, C is capacitance,${\mathrm{Î\mu }}_0$ is the permittivity of the free space,A is the area of cross-section, andd is the separation between the plates.

We can see that the capacitance of the parallel plate capacitor when dielectric material is placed between the plates will be depended only on the dielectric constant and the plate separation considering equation (i).

$C\mathrm{Î\pm }\frac{k}{d}$

Hence, to maximize the capacitance of the capacitor, we need to choose such a material whose $\frac{k}{d}$value should be greater.

For mica, the thickness a=0.10 mm and the dielectric constant$k=5.4$

$$\begin{gathered} C\mathrm{Î\pm }\frac{k}{d-a} \\ =\frac{5.4}{d-0.10mm} \end{gathered}$$

And for glass, the thickness b=2 mm and the dielectric constant $k=7$
$$\begin{gathered} C\mathrm{Î\pm }\frac{k}{d-a} \\ =\frac{7.0}{d-2mm} \end{gathered}$$

For paraffin, the thickness c=1.0 cm and the dielectric constant k=2

$$\begin{gathered} C\mathrm{Î\pm }\frac{k}{d-c} \\ =\frac{2}{d-1.0cm} \end{gathered}$$

Hence, from the aboveobservations, we can say that mica will have greater value of $\frac{k}{d}$.

Hence, a mica sheet will be placed to maximize the capacitance.