What voltage must be applied to an \({\bf{8}}{\bf{.00 nF}}\) capacitor to store \({\bf{0}}{\bf{.160}}\;{\bf{mC}}\) of charge?

A capacitor is a device used to store electrical energy and works in an electric field. It is a passive electrical component with two terminals. Capacitance is the term used to describe the effect of a capacitor.

Any pair of conductors separated by an insulating substance is referred to as a capacitor. When the capacitor is charged, the two conductors have charges of equal magnitude\(Q\)and opposite sign, and the positively charged conductor's potential\(\Delta V\)with respect to the negatively charged conductor is proportional to\(Q\)The ratio of\(Q\)to\(\Delta V\)determines the capacitance\(C\)

\(C = \frac{Q}{{\Delta V}}\)

The farad is the SI unit of capacitance (\(F\)):\(F = 1C/V\)

The capacitor's capacitance is:

\(\begin{array}{c}C = (8.00{\rm{ }}nF)\left( {\frac{{1\;F}}{{{{10}^9}{\rm{ }}nF}}} \right)\\ = 8.00 \times {10^{ - 9}}\;F\end{array}\)

The capacitor holds the following charge:

\(\begin{array}{c}Q = (0.160{\rm{ }}mC)\left( {\frac{{1{\rm{ }}C}}{{{{10}^3}{\rm{ }}mC}}} \right)\\ = 0.160 \times {10^{ - 3}}{\rm{ }}C\end{array}\)

Equation is used to calculate the potential difference across the capacitor.

\(\Delta V = \frac{Q}{C}\)

Substitute the values of\(Q\)and\(C\):

\(\begin{array}{c}V = \frac{{0.160 \times {{10}^{ - 3}}{\rm{ }}C}}{{8.00 \times {{10}^{ - 9}}\;F}}\\ = \left( {20.0 \times {{10}^3}\;V} \right)\left( {\frac{{1{\rm{ }}kV}}{{1000\;V}}} \right)\\ = 20.0{\rm{ }}kV\end{array}\)

Therefore, the voltage applied is \(20.0{\rm{ }}kV\).