Nuclear Binding Energy: Complete Explanation
Nuclear binding energy is the energy required to completely separate a nucleus into its individual
protons and
neutrons. It is also the energy released when nucleons come together to form a nucleus. This
energy holds the
nucleus together, overcoming the repulsive electrostatic force between protons.
### Mass-Energy Equivalence (Einstein's Equation)
The concept of nuclear binding energy is closely related to Einstein's equation:
E = mc^2
where mass and energy are interchangeable. When nucleons form a nucleus, some mass is lost
and converted into
binding energy. This lost mass is called the mass defect.
### Mass Defect and Binding Energy Calculation
Mass defect (Deltam) is given by:
Deltam = (total mass of protons and neutrons) - (mass of the nucleus)
The binding energy (E_b) is then calculated as:
E_b = Deltam x c^2
where:
- E_b = nuclear binding energy (Joules or MeV)
- Deltam = mass defect (kg or atomic mass units, u)
- c = speed of light (3 x 10^8 m/s)
Nuclear binding energy is the energy required to completely separate a nucleus into its individual
protons and
neutrons. It is also the energy released when nucleons come together to form a nucleus. This
energy holds the
nucleus together, overcoming the repulsive electrostatic force between protons.
### Mass-Energy Equivalence (Einstein's Equation)
The concept of nuclear binding energy is closely related to Einstein's equation:
E = mc^2
where mass and energy are interchangeable. When nucleons form a nucleus, some mass is lost
and converted into
binding energy. This lost mass is called the mass defect.
### Mass Defect and Binding Energy Calculation
Mass defect (Deltam) is given by:
Deltam = (total mass of protons and neutrons) - (mass of the nucleus)
The binding energy (E_b) is then calculated as:
E_b = Deltam x c^2
where:
- E_b = nuclear binding energy (Joules or MeV)
- Deltam = mass defect (kg or atomic mass units, u)
- c = speed of light (3 x 10^8 m/s)
