Coulomb's Law
- All charged particles generate an electric field
- This field exerts a force on charged particles which are nearby
- The electric force between two charges is defined by Coulomb’s law, which states that:
The electric force between two point charges is directly proportional to the product of the charges and inversely proportional to the square of their separation
- This electric force can be calculated using the expression:
- Where:
- F = electric force (N)
- q1, q2 = magnitudes of the charges (C)
- r = distance between the centres of the two charges (m)
- k = Coulomb constant (8.99 × 109 N m2 C–2)
- Coulomb's law for two charges is analogous to Newton's law of gravitation for two masses
- This means that electric and gravitational forces are very similar
- For example, both forces follow an inverse square law with the separation between charge or mass
Electrostatic attraction between two charges
The attractive electric force F between two point charges +q1 and −q2 with a separation of r is defined by Coulomb’s law
- Coulomb's constant is given by:
- Where ε0 is the permittivity of free space
- ε0 = 8.85 × 10–12 C2 N–1 m–2 and refers to charges in a vacuum
- The value of the permittivity of air is taken to be the same as ε0
- All other materials have a higher permittivity ε > ε0
- ε is a measure of the resistance offered by a material in creating an electric field within it
- The value of k depends on the material between the charges
- In a vacuum, k = 8.99 × 109 N m2 C–2
Repulsive & Attractive Forces
- Unlike the gravitational force between two masses which is only attractive, electric forces can be attractive or repulsive
- Between two charges of the same type:
- The product q1q2 is positive, so the forces have positive signs
- Positive forces mean the charges experience repulsion
- For two opposite charges:
- The product q1q2 is negative, so the forces have negative signs
- Negative forces mean the charges experience attraction
Worked example
An alpha particle is placed 2.0 mm from a gold nucleus in a vacuum.
Taking them as point charges, calculate the magnitude of the electric force acting between the nuclei.
- Proton number of helium = 2
- Proton number of gold = 79
Answer:
Step 1: Write down the known quantities
- Separation between charges, r = 2.0 mm = 2.0 × 10–3 m
- Elementary charge, e = 1.60 × 10–19 C (from the data booklet)
- Coulomb constant, k = 8.99 × 109 N m2 C–2 (from the data booklet)
Step 2: Calculate the charges of the alpha particle and gold nucleus
- An alpha particle (helium nucleus) has 2 protons, hence it has a charge of:
q1 = 2e = 2 × (1.60 × 10–19)
- A gold nucleus has 79 protons, hence it has a charge of:
q2 = 79e = 79 × (1.60 × 10–19)
Step 3: Write down Coulomb's law
Step 4: Substitute the values and calculate the magnitude of the electric force
N (2 s.f.)
Exam Tip
You do not need to memorise the numerical value of the Coulomb's constant k or that of the permittivity of free space ε0. They will both be given in the data booklet.
Unless specified in the question, you should assume that charges are located in a vacuum.
You should note that Coulomb's law can only be applied to charged spheres whose size is much smaller than their separation. Only in this case, the point charge approximation is valid. You must remember that the separation r must be taken from the centres of the spheres.
You cannot use Coulomb's law to calculate the electrostatic force between charges distributed on irregularly-shaped objects.