Electron-positron pairs

The formation of electron-positron pairs occurs when high energy γ radiation interacts with the electron shell of an atom. It is the highest energy possibility of the three γ-ray interactions with the shell.

At photon energies theoretically above 1,02 MeV, but practically much higher, the photon is converted near the atomic nucleus into a positron and an electron. At the same time, it is necessary that this happens near the atomic nucleus of another particle that can take over part of the momentum of the photon (since the momentum of the positron and electron is lower). Spontaneous transformation of a photon into an electron and a positron is not possible when it moves in a vacuum due to the law of conservation of the momentum (the sum of the momentum of the resulting electron and positron is less than the momentum supplied by the photon). The transformation itself takes place as a result of the electric field of the atomic nucleus(the greater the charge of the nucleus, the greater the probability of transformation). The kinetic energy of the created electron-positron pair is distributed randomly between the two particles.

The following equation can be used to express the energy balance of the given event:

$$hv = E_e +E_p + 2m_ec^2$$

It follows the given relationship that the energy of the photon must be greater than the energy, that represents the sum of the two masses of the electron (the sum of the rest energies of the electron and the positron are still the same).

The resulting particles lose their energy during interactions with the surrounding environment, i.e. ionization or excitation. However, the positron usually combines with the electron during the annihilation process and thus emits two quanta of electromagnetic radiation with an energy of 511 keV. These quanta move in the opposite direction.

Related articles

 * Photoelectric phenomenon
 * Compton scattering
 * Gamma radiation