Fields - Equipotentials and Field Lines

An electron is moved from an equipotential of $-200\text{ V}$ to an equipotential of $-500\text{ V}$. Calculate the work done on the electron in electronvolts ($\text{eV}$) and determine if the work is done by or against the field.

$\Delta V = V_{final} - V_{initial} = -500\text{ V} - (-200\text{ V}) = -300\text{ V}$. The charge of an electron is $q = -1e$. Work done $W = q\Delta V = (-1e) \times (-300\text{ V}) = 300\text{ eV}$.

Since the work done is positive ($300\text{ eV}$), work must be done against the electrostatic field to move the negative electron toward a more negative potential.

In a uniform electric field, two equipotential lines representing $100\text{ V}$ and $150\text{ V}$ are separated by a distance of $2.5\text{ cm}$. Calculate the electric field strength $E$.

$E = |\frac{\Delta V}{\Delta r}| = \frac{150\text{ V} - 100\text{ V}}{0.025\text{ m}} = \frac{50}{0.025} = 2000\text{ V m}^{-1}$.

The electric field strength is the negative gradient of the potential. In a uniform field, $E$ is constant and is calculated by dividing the potential difference by the perpendicular distance between the equipotentials.