Mass Defect & Nuclear Binding Energy
- Experiments into nuclear structure have found that the total mass of a nucleus is less than the sum of the masses of its constituent nucleons
- In other words, the combined mass of 6 separate protons and 6 separate neutrons is more than the mass of a carbon-12 nucleus
- This difference in mass is known as the mass defect
- Mass defect is defined as:
The difference between the measured mass of a nucleus and the sum total of the masses of its constituents
- The mass defect Δm of a nucleus can be calculated using:
- Where:
- Z = proton number
- A = nucleon number
- mp = mass of a proton (kg)
- mn = mass of a neutron (kg)
- mtotal = measured mass of the nucleus (kg)
A system of separated nucleons has a greater mass than a system of bound nucleons
- Due to mass-energy equivalence, a decrease in mass infers that energy must be released
- Energy and mass are proportional, so, the total energy of a nucleus is less than the sum of the energies of its constituent nucleons
- Binding energy is defined as:
The energy required to break a nucleus into its constituent protons and neutrons
- The formation of a nucleus from a system of isolated protons and neutrons releases energy
Worked example
The binding energy per nucleon is 7.98 MeV for an atom of Oxygen-16 (16O).
Determine an approximate value for the energy required, in MeV, to completely separate the nucleons of this atom.
Answer:
Step 1: List the known quantities
- Binding energy per nucleon, E = 7.98 MeV
Step 2: State the number of nucleons
- The number of nucleons is 8 protons and 8 neutrons, therefore 16 nucleons in total
Step 3: Find the total binding energy
- The binding energy for oxygen-16 is:
7.98 × 16 = 127.7 MeV
Step 4: State the final answer
- The approximate total energy needed to completely separate this nucleus is 127.7 MeV
Exam Tip
The terms binding energy and mass defect can cause students confusion, so be careful when using them in your explanations.
Avoid describing the binding energy as the energy stored in the nucleus – this is not correct – it is energy that must be put into the nucleus to separate all the nucleons.
The same goes for the term mass defect, make sure to only use this when all the nucleons are separated and not to describe the decrease in mass which occurs during radioactive decay.