91影视

The plates of capacitor $2$ are closer to each other as compared to capacitor$1$.

The ability of a capacitor to store energy in the form of an electric field is known as capacitance. It is the ratio of charge accumulated on the plate to the potential difference developed between the plates.

Consider a parallel plate capacitor, having an area of cross-section 鈥楢鈥�. The separation between the plates is s, and there is no layer of insulating material between them. Thus, the material between the plates is free space. When connected to a circuit, the electric field, developed between the plates, is given as-

$$\begin{gathered} E=\frac{蟽}{{蔚}_o} \\ =\frac{{\displaystyle \raisebox{1ex}{$Q$}\!\left/ \!\raisebox{-1ex}{$A$}\right.}}{{蔚}_o} \end{gathered}$$

Here, $Q$is the charge gathered on the plates,localid="1662168754855" ${蔚}_o$is the permittivity of free space and localid="1662168738233" $蟽$is the surface charge density.

The potential difference$\left(鈭�V\right)$developed between the plates is given as-

localid="1662170000699" $$\begin{gathered} 鈭�V=E.s \\ =\left(\frac{{\displaystyle \raisebox{1ex}{$Q$}\!\left/ \!\raisebox{-1ex}{$A$}\right.}}{{蔚}_o}\right)s \end{gathered}$$

In the above equation, the potential difference produced between the plates is directly proportional to the separation between the plates. The larger the separation, the larger will be the potential difference, and the higher will be the rate of accumulation of charge. Hence, the current will decrease more rapidly.

Therefore, if the separation between the plates of the parallel plate capacitor is less, the current will decrease less rapidly.