18.2 Coulomb's law - Physics | OpenStax (2024)

Table of Contents

Section Learning Objectives Teacher Support Teacher Support Section Key Terms Teacher Support Teacher Support Teacher Support Teacher Support Watch Physics Electrostatics (part 1): Introduction to charge and Coulomb's law Grasp Check Snap Lab Hovering plastic Grasp Check Worked Example Using Coulomb’s law to find the force between charged objects Strategy Worked Example Using Coulomb’s law to find the distance between charged objects Strategy Practice Problems Check Your Understanding FAQs References

Section Learning Objectives

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

Describe Coulomb’s law verbally and mathematically
Solve problems involving Coulomb’s law

Teacher Support

The learning objectives in this section will help your students master the following standards:

(5) The student knows the nature of forces in the physical world. The student is expected to:
- (C)describe and calculate how the magnitude of the electrical force between two objects depends on their charges and the distance between them.

Section Key Terms

Coulomb’s law

inverse-square law

Teacher Support

This section presents Coulomb’s law and points out its similarities and differences with respect to Newton’s law of universal gravitation. The similarities include the inverse-square nature of the two laws and the analogous roles of mass and charge. The differences include the restriction of positive mass versus positive or negative charge.

[BL][OL]Discuss how Coulomb described this law long after Newton described the law of universal gravitation.

[AL]Ask why the law of force between electrostatic charge was discovered after that of gravity if gravity is weak compared to electrostatic forces.

More than 100 years before Thomson and Rutherford discovered the fundamental particles that carry positive and negative electric charges, the French scientist Charles-Augustin de Coulomb mathematically described the force between charged objects. Doing so required careful measurements of forces between charged spheres, for which he built an ingenious device called a torsion balance.

This device, shown in Figure 18.15, contains an insulating rod that is hanging by a thread inside a glass-walled enclosure. At one end of the rod is the metallic sphere A. When no charge is on this sphere, it touches sphere B. Coulomb would touch the spheres with a third metallic ball (shown at the bottom of the diagram) that was charged. An unknown amount of charge would distribute evenly between spheres A and B, which would then repel each other, because like charges repel. This force would cause sphere A to rotate away from sphere B, thus twisting the wire until the torsion in the wire balanced the electrical force. Coulomb then turned the knob at the top, which allowed him to rotate the thread, thus bringing sphere A closer to sphere B. He found that bringing sphere A twice as close to sphere B required increasing the torsion by a factor of four. Bringing the sphere three times closer required a ninefold increase in the torsion. From this type of measurement, he deduced that the electrical force between the spheres was inversely proportional to the distance squared between the spheres. In other words,

$F \propto \frac{1}{r^{2,}}$

18.5

where r is the distance between the spheres.

An electrical charge distributes itself equally between two conducting spheres of the same size. Knowing this allowed Coulomb to divide an unknown charge in half. Repeating this process would produce a sphere with one quarter of the initial charge, and so on. Using this technique, he measured the force between spheres A and B when they were charged with different amounts of charge. These measurements led him to deduce that the force was proportional to the charge on each sphere, or

$F \propto q_{A} q_{B,}$

18.6

where $q_{A}$ is the charge on sphere A, and $q_{B}$ is the charge on sphere B.

18.2 Coulomb's law - Physics | OpenStax (1)

Figure 18.15 A drawing of Coulomb’s torsion balance, which he used to measure the electrical force between charged spheres. (credit: Charles-Augustin de Coulomb)

Combining these two proportionalities, he proposed the following expression to describe the force between the charged spheres.

$F = \frac{k q_{1} q_{2}}{r^{2}}$

18.7

This equation is known as Coulomb’s law, and it describes the electrostatic force between charged objects. The constant of proportionality k is called Coulomb’s constant. In SI units, the constant k has the value $k = 8.99 \times 10^{9} N \cdot m^{2} {/C}^{2.}$

The direction of the force is along the line joining the centers of the two objects. If the two charges are of opposite signs, Coulomb’s law gives a negative result. This means that the force between the particles is attractive. If the two charges have the same signs, Coulomb’s law gives a positive result. This means that the force between the particles is repulsive. For example, if both $q_{1}$ and $q_{2}$ are negative or if both are positive, the force between them is repulsive. This is shown in Figure 18.16(a). If $q_{1}$ is a negative charge and $q_{2}$ is a positive charge (or vice versa), then the charges are different, so the force between them is attractive. This is shown in Figure 18.16(b).

18.2 Coulomb's law - Physics | OpenStax (2)

Figure 18.16 The magnitude of the electrostatic force F between point charges q₁ and q₂ separated by a distance r is given by Coulomb’s law. Note that Newton’s third law (every force exerted creates an equal and opposite force) applies as usual—the force (F₁,₂) on q₁ is equal in magnitude and opposite in direction to the force (F₂,₁) it exerts on q₂. (a) Like charges. (b) Unlike charges.

Teacher Support

Point out how the subscripts ₁, ₂ means the force on object 1 due to object 2 (and vice versa).

Watch Physics

Electrostatics (part 1): Introduction to charge and Coulomb's law

This video explains the basics of Coulomb’s law. Note that the lecturer uses d for the distance between the center of the particles instead of r.

Access multimedia content

Grasp Check

True or false—If one particle carries a positive charge and another carries a negative charge, then the force between them is attractive.

true
false

Snap Lab

Hovering plastic

In this lab, you will use electrostatics to hover a thin piece of plastic in the air.

Balloon
Light plastic bag (e.g., produce bag from grocery store)

Instructions

Procedure

Cut the plastic bag to make a plastic loop about 2 inches wide.
Inflate the balloon.
Charge the balloon by rubbing it on your clothes.
Charge the plastic loop by placing it on a nonmetallic surface and rubbing it with a cloth.
Hold the balloon in one hand, and in the other hand hold the plastic loop above the balloon. If the loop clings too much to your hand, recruit a friend to hold the strip above the balloon with both hands. Now let go of the plastic loop, and maneuver the balloon under the plastic loop to keep it hovering in the air above the balloon.

Grasp Check

How does the balloon keep the plastic loop hovering?

The balloon and the loop are both negatively charged. This will help the balloon keep the plastic loop hovering.
The balloon is charged, while the plastic loop is neutral.This will help the balloon keep the plastic loop hovering.
The balloon and the loop are both positively charged. This will help the balloon keep the plastic loop hovering.
The balloon is positively charged, while the plastic loop is negatively charged. This will help the balloon keep the plastic loop hovering.

Worked Example

Using Coulomb’s law to find the force between charged objects

Suppose Coulomb measures a force of $20 \times 10^{−6} N$ between the two charged spheres when they are separated by 5.0 cm. By turning the dial at the top of the torsion balance, he approaches the spheres so that they are separated by 3.0 cm. Which force does he measure now?

Strategy

Apply Coulomb’s law to the situation before and after the spheres are brought closer together. Although we do not know the charges on the spheres, we do know that they remain the same. We call these unknown but constant charges $q_{1}$ and $q_{2}$ . Because these charges appear as a product in Coulomb’s law, they form a single unknown. We thus have two equations and two unknowns, which we can solve. The first unknown is the force (which we call $F_{f}$ ) when the spheres are 3.0 cm apart, and the second is $q_{1} q_{2}$ .

Use the following notation: When the charges are 5.0 cm apart, the force is $F_{i} = 20 \times 10^{−6} N$ and $r_{i} = 5.0 cm = 0.050 m$ , where the subscript i means initial. Once the charges are brought closer together, we know $r_{f} = 3.0 cm = 0.030 m$ , where the subscript f means final.

Solution

Coulomb’s law applied to the spheres in their initial positions gives

$F_{i} = \frac{k q_{1} q_{2}}{r_{i}^{2.}} .$

18.8

Coulomb’s law applied to the spheres in their final positions gives

$F_{f} = \frac{k q_{1} q_{2}}{r_{f}^{2.}} .$

18.9

Dividing the second equation by the first and solving for the final force $F_{f}$ leads to

$\begin{matrix} \frac{F_{f}}{F_{i}} & = & \frac{k q_{1} q_{2} / r_{f}^{2}}{k q_{1} q_{2} / r_{i}^{2}} . \\ = & \frac{r_{i}^{2}}{r_{f}^{2}} \\ F_{f} & = & F_{i} \frac{r_{i}^{2}}{r_{f}^{2}} . \end{matrix}$

18.10

Inserting the known quantities yields

$\begin{matrix} F_{f} & = & F_{i} \frac{r_{i}^{2}}{r_{f}^{2}} \\ = & (20 \times 10^{−6} N) \frac{{(0.050 m)}^{2}}{{(0.030 m)}^{2}} \\ = & 56 \times 10^{−6} N \\ = & 5.6 \times 10^{−5} N. \end{matrix}$

18.11

The force acts along the line joining the centers of the spheres. Because the same type of charge is on each sphere, the force is repulsive.

Worked Example

Using Coulomb’s law to find the distance between charged objects

An engineer measures the force between two ink drops by measuring their acceleration and their diameter. She finds that each member of a pair of ink drops exerts a repulsive force of $F = 5.5 mN$ on its partner. If each ink drop carries a charge $q_{ink drop} = −1 \times 10^{−10} C$ , how far apart are the ink drops?

Strategy

We know the force and the charge on each ink drop, so we can solve Coulomb’s law for the distance r between the ink drops. Do not forget to convert the force into SI units: $F = 5.5 mN = 5.5 \times 10^{−3} N.$

Solution

The charges in Coulomb’s law are $q_{1} = q_{2} = q_{ink drop}^{},$ so the numerator in Coulomb’s law takes the form $q_{1} q_{2} = q_{ink drop}^{2}$ . Inserting this into Coulomb’s law and solving for the distance r gives

$\begin{matrix} F & = & \frac{k q_{ink drop}^{2}}{r^{2}} \\ r & = & \pm \sqrt{\frac{k q_{ink drop}^{2}}{F}} \\ = & \pm \sqrt{\frac{(8.99 \times 10^{9} N \cdot m^{2} {/C}^{2}) {(−1 \times 10^{−10} C)}^{2}}{5.5 \times 10^{−3} N}} \\ = & \pm 1.3 \times 10^{−4} m \end{matrix}$

18.14

or 130 microns (about one-tenth of a millimeter).

Discussion

The plus-minus sign means that we do not know which ink drop is to the right and which is to the left, but that is not important, because both ink drops are the same.

Practice Problems

11.

A charge of −4 × 10⁻⁹ C is a distance of 3 cm from a charge of 3 × 10⁻⁹ C . What is the magnitude and direction of the force between them?

1.2 × 10⁻⁴ N, and the force is attractive
1.2 × 10¹⁴ N, and the force is attractive
6.74 × 10²³ N, and the force is attractive
−ŷ, and the force is attractive

12.

Two charges are repelled by a force of 2.0 N. If the distance between them triples, what is the force between the charges?

0.22 N
0.67 N
2.0 N
18.0 N

Check Your Understanding

13.

How are electrostatic force and charge related?

The force is proportional to the product of two charges.
The force is inversely proportional to the product of two charges.
The force is proportional to any one of the charges between which the force is acting.
The force is inversely proportional to any one of the charges between which the force is acting.

14.

Why is Coulomb’s law called an inverse-square law?

because the force is proportional to the inverse of the distance squared between charges
because the force is proportional to the product of two charges
because the force is proportional to the inverse of the product of two charges
because the force is proportional to the distance squared between charges

FAQs

18.2 Coulomb's law - Physics | OpenStax? ›

This equation is known as Coulomb's law, and it describes the electrostatic force between charged objects. The constant of proportionality k is called Coulomb's constant. In SI units, the constant k has the value k = 8.99 × 10 9 N ⋅ m 2 /C 2. k = 8.99 × 10 9 N ⋅ m 2 /C 2.

Discover More Details ›

What is the Coulomb's law statement in physics? ›

The law states that the magnitude, or absolute value, of the attractive or repulsive electrostatic force between two point charges is directly proportional to the product of the magnitudes of their charges and inversely proportional to the square of the distance between them.

Learn More Now ›

What is Coulomb's law number? ›

Coulomb's law calculates the magnitude of the force F between two point charges, q1 and q2, separated by a distance r. F=k|q1q2|r2. k=8.988×109N⋅m2C2≈8.99×109N⋅m2C2. Although the formula for Coulomb's law is simple, it was no mean task to prove it.

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What is the Coulomb's law for F? ›

Coulomb's force is attraction or repulsive force between two charges namely q1 and q2. F= E×q1×q2/r^2 ,where E is constant,r is distance between two charges. Consider unit charges and unit distance F=qE.

What is 18.2 Coulomb's law? ›

Note that Coulomb's law applies only to charged objects that are not moving with respect to each other. The law says that the force is proportional to the amount of charge on each object and inversely proportional to the square of the distance between the objects.

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What are the 3 parts of Coulomb's law? ›

Coulomb's Law Equation

where Q₁ represents the quantity of charge on object 1 (in Coulombs), Q₂ represents the quantity of charge on object 2 (in Coulombs), and d represents the distance of separation between the two objects (in meters).

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How to solve Coulomb's law? ›

Coulomb's law describes the strength of the electrostatic force (attraction or repulsion) between two charged objects. The electrostatic force is equal to the charge of object 1 times the charge of object 2, divided by the distance between the objects squared, all times the Coulomb constant (k).

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What is a real life example of Coulomb's law? ›

Another example of Coulomb's law is the comb and small pieces of paper. When a comb is rubbed against the hair, it gets charged. This charged comb can attract small pieces of paper that have opposite charges. Mixing substances in the water also follow Coulomb's law.

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How to calculate coulombs? ›

Electricity allows us to calculate the amount of charge passed ( , in coulombs, C) by multiplying the electric current ( , in amps, A) by the time ( , in seconds, s).

What is Coulomb's law Grade 11 physics? ›

Coloumb's Law is the electrostatic force of attraction or repulsion between two charged objects is directly proportional to the product of the charges and inversely proportional to the square of the distance between their centres. are the magnitudes of charge on charge 1 and charge 2 respectively.

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What does Coulomb's law translate? ›

Coulomb's law states that two electric charges of the same sign will repel each other as the inverse square of the distance. This example is from Wikipedia and may be reused under a CC BY-SA license. Coulomb's law can also be stated as a simple mathematical expression.

What is the Coulomb's law given by F? ›

Coulomb's law is an equation that calculates the magnitude of the electrostatic force between two point charges. The equation is given by F = k * q1 * q2 / r^2, where F is the force, q1 and q2 are the charges, r is the distance between the charges, and k is Coulomb's constant.

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What is the Coulomb's law statement? ›

Charles-Augustin de Coulomb, a French physicist in 1784, measured the force between two point charges and he came up with the theory that the force is inversely proportional to the square of the distance between the charges.

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What is the Coulomb's law mathematically? ›

Coulomb's Law Formula

Coulomb's Law finds out the magnitude of the electrostatic force between the charges. The unit of the electrostatic force is Newton (N). Electrostatic force = (Coulomb constant) absolute value of (charge 1) (charge 2)/ (distance between charges)2. F = k\frac{\left | q_{1}q_{2} \right |}{r^{2}}

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What is the correct formula for Coulomb's law? ›

Strategy. To compare the two forces, we first compute the electrostatic force using Coulomb's law, F=k∣q1q2∣r2 F = k ∣ q 1 q 2 ∣ r 2 . We then calculate the gravitational force using Newton's universal law of gravitation. Finally, we take a ratio to see how the forces compare in magnitude.

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What is the Coulomb's second law? ›

Coulomb's second law:- the magnitude of force between two bodies when placed near to each other is directly proportional to product of their strength and inversly proportional to the square of distance between them.

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What is the Coulomb's law in words? ›

: a statement in physics: the force of attraction or repulsion acting along a straight line between two electric charges is directly proportional to the product of the charges and inversely to the square of the distance between them.