Binding Energy per Nucleon Graph

When comparing the stability of different nuclei, it is useful to look at the binding energy per nucleon
The binding energy per nucleon is defined as:

The binding energy of a nucleus divided by the number of nucleons in the nucleus

A higher binding energy per nucleon indicates a higher stability since it requires more energy to pull the nucleus apart

Iron (A = 56) has the highest binding energy per nucleon, which makes it the most stable of all the elements

Binding Energy per Nucleon

By plotting a graph of binding energy per nucleon against nucleon number, the stability of elements can be inferred

Key Features of the Graph

At low values of A:
- Nuclei tend to have a lower binding energy per nucleon, hence, they are generally less stable
- This means the lightest elements have weaker electrostatic forces and are the most likely to undergo fusion
Helium (⁴He), carbon (¹²C) and oxygen (¹⁶O) do not fit the trend
- Helium-4 is a particularly stable nucleus hence it has a high binding energy per nucleon
- Carbon-12 and oxygen-16 can be considered to be three and four helium nuclei, respectively, bound together
At high values of A:
- The general binding energy per nucleon is high and gradually decreases with A
- This means the heaviest elements are the most unstable and likely to undergo fission

Worked example

Determine the binding energy per nucleon of Iron-56 ( ${}_{26}^{56}F e$ ) in MeV

Mass of a neutron = 1.675 × 10⁻²⁷ kg

Mass of a proton = 1.673 × 10⁻²⁷ kg

Mass of a ${}_{26}^{56}F e$ nucleus = 9.288 × 10⁻²⁶ kg

Step 1: Calculate the mass defect

Number of protons, Z = 26

Number of neutrons, A – Z = 56 – 26 = 30

Mass defect, Δm = Zm_p + (A – Z)m_n – m_total

Δm = (26 × 1.673 × 10^-27) + (30 × 1.675 × 10^-27) – (9.288 × 10^-26)

Δm = 8.680 × 10^-28 kg

Step 2: Calculate the binding energy of the nucleus

Binding energy, ΔE = Δmc²

E = (8.680 × 10^-28) × (3.00 × 10⁸)² = 7.812 × 10^-11 J

Step 3: Calculate the binding energy per nucleon

Binding energy per nucleon = $\frac{E}{A}$

$\frac{E}{H} = \frac{7.812 \times 10^{- 11}}{56} = 1.395 \times 10^{- 12} J$

Step 4: Convert to MeV

J → eV: divide by 1.6 × 10^-19

eV → MeV: divide by 10⁶

binding energy per nucleon = $\frac{1.395 \times 10^{- 12}}{1.6 \times 10^{- 19}} = 8 718 750 e V = 8.7 M e V (2 s . f)$

Examiner Tip

Checklist on what to include (and what not to include) in an exam question asking you to draw a graph of binding energy per nucleon against nucleon number:

You will be expected to draw the best fit curve AND a cross to show the anomaly that is Helium
Do not begin your curve at A = 0, this is not a nucleus!
Make sure to correctly label both axes AND units for binding energy per nucleon
You will be expected to include numbers on the axes, mainly at the peak to show the position of iron (⁵⁶Fe)

Binding Energy per Nucleon Graph (Edexcel International A Level Physics)

Revision Note