7.1 Electric Potential Energy

Samuel J. Ling; William Moebs; Jeff Sanny

Chapter 7. Electric Potential

7.1 Electric Potential Energy

Learning Objectives

By the end of this section, you will be able to:

Define the work done by an electric force
Define electric potential energy
Apply work and potential energy in systems with electric charges

When a free positive charge q is accelerated by an electric field, it is given kinetic energy (Figure 7.2). The process is analogous to an object being accelerated by a gravitational field, as if the charge were going down an electrical hill where its electric potential energy is converted into kinetic energy, although of course the sources of the forces are very different. Let us explore the work done on a charge q by the electric field in this process, so that we may develop a definition of electric potential energy.

The first part of the figure shows two charged plates – one positive and one negative. A positive charge q is located between the plates and moves from point A to B. The second part of the figure shows a mass m rolling down a hill. — **Figure 7.2** A charge accelerated by an electric field is analogous to a mass going down a hill. In both cases, potential energy decreases as kinetic energy increases, [latex]–\Delta U=\Delta K[/latex]. Work is done by a force, but since this force is conservative, we can write [latex]W=–\text{Δ}U[/latex].

The electrostatic or Coulomb force is conservative, which means that the work done on q is independent of the path taken, as we will demonstrate later. This is exactly analogous to the gravitational force. When a force is conservative, it is possible to define a potential energy associated with the force. It is usually easier to work with the potential energy (because it depends only on position) than to calculate the work directly.

To show this explicitly, consider an electric charge [latex]+q[/latex] fixed at the origin and move another charge [latex]+Q[/latex] toward q in such a manner that, at each instant, the applied force [latex]\stackrel{\to }{\textbf{F}}[/latex] exactly balances the electric force [latex]{\stackrel{\to }{\textbf{F}}}_{e}[/latex] on Q (Figure 7.3). The work done by the applied force [latex]\stackrel{\to }{\textbf{F}}[/latex] on the charge Q changes the potential energy of Q. We call this potential energy the electrical potential energy of Q.

The figure shows two positive charges – fixed charge q and moving test charge Q and the forces on Q when is moved closer to q, from point P subscript 1 to point P subscript 2. — **Figure 7.3** Displacement of “test” charge Q in the presence of fixed “source” charge q.

The work [latex]{W}_{12}[/latex] done by the applied force [latex]\stackrel{\to }{\textbf{F}}[/latex] when the particle moves from [latex]{P}_{1}[/latex] to [latex]{P}_{2}[/latex] may be calculated by

[latex]{W}_{12}={\int }_{{P}_{1}}^{{P}_{2}}\stackrel{\to }{\textbf{F}}·d\stackrel{\to }{\textbf{l}}.[/latex]

Since the applied force [latex]\stackrel{\to }{\textbf{F}}[/latex] balances the electric force [latex]{\stackrel{\to }{\textbf{F}}}_{e}[/latex] on Q, the two forces have equal magnitude and opposite directions. Therefore, the applied force is

[latex]\stackrel{\to }{\textbf{F}}=\text{−}\stackrel{\to }{\textbf{F}_{e}}=-\frac{kqQ}{{r}^{2}}\hat{\textbf{r}},[/latex]

where we have defined positive to be pointing away from the origin and r is the distance from the origin. The directions of both the displacement and the applied force in the system in Figure 7.3 are parallel, and thus the work done on the system is positive.

We use the letter U to denote electric potential energy, which has units of joules (J). When a conservative force does negative work, the system gains potential energy. When a conservative force does positive work, the system loses potential energy, [latex]\text{Δ}U=\text{−}W.[/latex] In the system in Figure 7.3, the Coulomb force acts in the opposite direction to the displacement; therefore, the work is negative. However, we have increased the potential energy in the two-charge system.

Example

Kinetic Energy of a Charged Particle

A [latex]+3.0\text{-nC}[/latex] charge Q is initially at rest a distance of 10 cm ([latex]{r}_{1}[/latex]) from a [latex]+5.0\text{-nC}[/latex] charge q fixed at the origin (Figure 7.4). Naturally, the Coulomb force accelerates Q away from q, eventually reaching 15 cm ([latex]{r}_{2}[/latex]).

The figure shows two positive charges, q (+5.0nC) and Q (+3.0nC) and the repelling force on Q, marked as F subscript e. Q is located at r subscript 1 = 10cm and F subscript e vector is towards r subscript 2 = 15cm. — **Figure 7.4** The charge Q is repelled by q, thus having work done on it and gaining kinetic energy.

What is the work done by the electric field between [latex]{r}_{1}[/latex] and [latex]{r}_{2}[/latex]?
How much kinetic energy does Q have at [latex]{r}_{2}[/latex]?

Strategy

Calculate the work with the usual definition. Since Q started from rest, this is the same as the kinetic energy.

Solution

Show Answer

Integrating force over distance, we obtain

[latex]\begin{array}{cc}{W}_{12}\hfill & ={\int }_{{r}_{1}}^{{r}_{2}}\stackrel{\to }{\textbf{F}}·d\stackrel{\to }{\textbf{r}}={\int }_{{r}_{1}}^{{r}_{2}}\frac{kqQ}{{r}^{2}}\phantom{\rule{0.2em}{0ex}}dr={\left[-\frac{kqQ}{r}\right]}_{{r}_{1}}^{{r}_{2}}=kqQ\left[\frac{-1}{{r}_{2}}+\frac{1}{{r}_{1}}\right]\hfill \\ & =\left(8.99\phantom{\rule{0.2em}{0ex}}×\phantom{\rule{0.2em}{0ex}}{10}^{9}\phantom{\rule{0.2em}{0ex}}{\text{Nm}}^{2}{\text{/C}}^{2}\right)\left(5.0\phantom{\rule{0.2em}{0ex}}×\phantom{\rule{0.2em}{0ex}}{10}^{-9}\phantom{\rule{0.2em}{0ex}}\text{C}\right)\left(3.0\phantom{\rule{0.2em}{0ex}}×\phantom{\rule{0.2em}{0ex}}{10}^{-9}\phantom{\rule{0.2em}{0ex}}\text{C}\right)\left[\frac{-1}{0.15\phantom{\rule{0.2em}{0ex}}\text{m}}+\frac{1}{0.10\phantom{\rule{0.2em}{0ex}}\text{m}}\right]\hfill \\ & =4.5\phantom{\rule{0.2em}{0ex}}×\phantom{\rule{0.2em}{0ex}}{10}^{-7}\phantom{\rule{0.2em}{0ex}}\text{J}\text{.}\hfill \end{array}[/latex]

This is also the value of the kinetic energy at [latex]{r}_{2}.[/latex]

Significance

Charge Q was initially at rest; the electric field of q did work on Q, so now Q has kinetic energy equal to the work done by the electric field.

Check Your Understanding

If Q has a mass of [latex]4.00\phantom{\rule{0.2em}{0ex}}\mu \text{g},[/latex] what is the speed of Q at [latex]{r}_{2}?[/latex]

Show Solution

[latex]K=\frac{1}{2}\phantom{\rule{0.2em}{0ex}}m{v}^{2},\phantom{\rule{0.2em}{0ex}}v=\sqrt{2\frac{K}{m}}=\sqrt{2\frac{4.5\phantom{\rule{0.2em}{0ex}}×\phantom{\rule{0.2em}{0ex}}{10}^{-7}\phantom{\rule{0.2em}{0ex}}\text{J}}{4.00\phantom{\rule{0.2em}{0ex}}×\phantom{\rule{0.2em}{0ex}}{10}^{-9}\phantom{\rule{0.2em}{0ex}}\text{kg}}}=15\phantom{\rule{0.2em}{0ex}}\text{m/s}[/latex]

In this example, the work W done to accelerate a positive charge from rest is positive and results from a loss in U, or a negative [latex]\text{Δ}U[/latex]. A value for U can be found at any point by taking one point as a reference and calculating the work needed to move a charge to the other point.

Electric Potential Energy

Work W done to accelerate a positive charge from rest is positive and results from a loss in U, or a negative [latex]\text{Δ}U[/latex]. Mathematically,

[latex]W=\text{−}\text{Δ}U.[/latex]

Gravitational potential energy and electric potential energy are quite analogous. Potential energy accounts for work done by a conservative force and gives added insight regarding energy and energy transformation without the necessity of dealing with the force directly. It is much more common, for example, to use the concept of electric potential energy than to deal with the Coulomb force directly in real-world applications.

In polar coordinates with q at the origin and Q located at r, the displacement element vector is [latex]d\stackrel{\to }{\textbf{l}}=\hat{\textbf{r}}\phantom{\rule{0.2em}{0ex}}dr[/latex] and thus the work becomes

[latex]{W}_{12}=\text{−}kqQ{\int }_{{r}_{1}}^{{r}_{2}}\frac{1}{{r}^{2}}\hat{\textbf{r}}·\hat{\textbf{r}}dr=kqQ\frac{1}{{r}_{2}}-kqQ\frac{1}{{r}_{1}}.[/latex]

Notice that this result only depends on the endpoints and is otherwise independent of the path taken. To explore this further, compare path [latex]{P}_{1}[/latex] to [latex]{P}_{2}[/latex] with path [latex]{P}_{1}{P}_{3}{P}_{4}{P}_{2}[/latex] in Figure 7.5.

The figure shows two positive charges, q and Q and the repelling force on Q. There are four points P subscript 1, P subscript 2, P subscript 3 and P subscript 4 where P subscript 1 P subscript 3 and P subscript 2 P subscript 4 form two concentric segments centered at q. The force on Q is perpendicular to direction of displacement when Q moves from P subscript 1 to P subscript 3 or P subscript 3 to P subscript 2. — **Figure 7.5** Two paths for displacement [latex]{P}_{1}[/latex] to [latex]{P}_{2}.[/latex] The work on segments [latex]{P}_{1}{P}_{3}[/latex] and [latex]{P}_{4}{P}_{2}[/latex] are zero due to the electrical force being perpendicular to the displacement along these paths. Therefore, work on paths [latex]{P}_{1}{P}_{2}[/latex] and [latex]{P}_{1}{P}_{3}{P}_{4}{P}_{2}[/latex] are equal.

The segments [latex]{P}_{1}{P}_{3}[/latex] and [latex]{P}_{4}{P}_{2}[/latex] are arcs of circles centered at q. Since the force on Q points either toward or away from q, no work is done by a force balancing the electric force, because it is perpendicular to the displacement along these arcs. Therefore, the only work done is along segment [latex]{P}_{3}{P}_{4},[/latex] which is identical to [latex]{P}_{1}{P}_{2}.[/latex]

One implication of this work calculation is that if we were to go around the path [latex]{P}_{1}{P}_{3}{P}_{4}{P}_{2}{P}_{1},[/latex] the net work would be zero (Figure 7.6). Recall that this is how we determine whether a force is conservative or not. Hence, because the electric force is related to the electric field by [latex]\stackrel{\to }{\textbf{F}}=q\stackrel{\to }{\textbf{E}}[/latex], the electric field is itself conservative. That is,

[latex]\oint \stackrel{\to }{\textbf{E}}·d\stackrel{\to }{\textbf{l}}=0.[/latex]

Note that Q is a constant.

Another implication is that we may define an electric potential energy. Recall that the work done by a conservative force is also expressed as the difference in the potential energy corresponding to that force. Therefore, the work [latex]{W}_{\text{ref}}[/latex] to bring a charge from a reference point to a point of interest may be written as

[latex]{W}_{\text{ref}}={\int }_{{r}_{\text{ref}}}^{r}\stackrel{\to }{\textbf{F}}·d\stackrel{\to }{\textbf{l}}[/latex]

and, by Equation 7.1, the difference in potential energy [latex]\left({U}_{2}-{U}_{1}\right)[/latex] of the test charge Q between the two points is

[latex]\text{Δ}U=\text{−}{\int }_{{r}_{\text{ref}}}^{r}\stackrel{\to }{\textbf{F}}·d\stackrel{\to }{\textbf{l}}.[/latex]

Therefore, we can write a general expression for the potential energy of two point charges (in spherical coordinates):

[latex]\text{Δ}U=\text{−}{\int }_{{r}_{\text{ref}}}^{r}\frac{kqQ}{{r}^{2}}dr=\text{−}{\left[-\frac{kqQ}{r}\right]}_{{r}_{\text{ref}}}^{r}=kqQ\left[\frac{1}{r}-\frac{1}{{r}_{\text{ref}}}\right].[/latex]

We may take the second term to be an arbitrary constant reference level, which serves as the zero reference:

[latex]U\left(r\right)=k\frac{qQ}{r}-{U}_{\text{ref}}.[/latex]

A convenient choice of reference that relies on our common sense is that when the two charges are infinitely far apart, there is no interaction between them. (Recall the discussion of reference potential energy in Potential Energy and Conservation of Energy.) Taking the potential energy of this state to be zero removes the term [latex]{U}_{\text{ref}}[/latex] from the equation (just like when we say the ground is zero potential energy in a gravitational potential energy problem), and the potential energy of Q when it is separated from q by a distance r assumes the form

[latex]U\left(r\right)=k\frac{qQ}{r}\phantom{\rule{0.2em}{0ex}}\left(z\text{ero reference at}\phantom{\rule{0.2em}{0ex}}r=\infty \right).[/latex]

This formula is symmetrical with respect to q and Q, so it is best described as the potential energy of the two-charge system.