Quantum mechanical scattering of photon and nucleus
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In pair production, a photon creates an electron positron pair. In the process of photons scattering in air (e.g. in
lightning Lightning is a naturally occurring electrostatic discharge during which two electrically charged regions, both in the atmosphere or with one on the ground, temporarily neutralize themselves, causing the instantaneous release of an average ...
discharges), the most important interaction is the scattering of photons at the nuclei of
atoms Every atom is composed of a nucleus and one or more electrons bound to the nucleus. The nucleus is made of one or more protons and a number of neutrons. Only the most common variety of hydrogen has no neutrons. Every solid, liquid, gas ...
or
molecules A molecule is a group of two or more atoms held together by attractive forces known as chemical bonds; depending on context, the term may or may not include ions which satisfy this criterion. In quantum physics, organic chemistry, and bio ...
. The full
quantum mechanical Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistry, qua ...
process of pair production can be described by the quadruply differential cross section given here: \begin d^4\sigma &= \frac, \mathbf_+, , \mathbf_-, \frac\frac\times \\ &\times\left \frac\left (4E_+^2-c^2\mathbf^2\right)\right.\\ &-\frac\left (4E_-^2-c^2\mathbf^2\right) \\ &+2\hbar^2\omega^2\frac \\ &+2\left.\frac\left(2E_+^2+2E_-^2-c^2\mathbf^2\right)\right \\ \end with \begin d\Omega_+&=\sin\Theta_+\ d\Theta_+,\\ d\Omega_-&=\sin\Theta_-\ d\Theta_-. \end This expression can be derived by using a quantum mechanical symmetry between pair production and
Bremsstrahlung ''Bremsstrahlung'' (), from "to brake" and "radiation"; i.e., "braking radiation" or "deceleration radiation", is electromagnetic radiation produced by the deceleration of a charged particle when deflected by another charged particle, typical ...
.
Z is the
atomic number The atomic number or nuclear charge number (symbol ''Z'') of a chemical element is the charge number of an atomic nucleus. For ordinary nuclei, this is equal to the proton number (''n''p) or the number of protons found in the nucleus of ever ...
, \alpha_\approx 1/137 the
fine structure constant In physics, the fine-structure constant, also known as the Sommerfeld constant, commonly denoted by (the Greek letter ''alpha''), is a fundamental physical constant which quantifies the strength of the electromagnetic interaction between ele ...
, \hbar the reduced Planck's constant and c the
speed of light The speed of light in vacuum, commonly denoted , is a universal physical constant that is important in many areas of physics. The speed of light is exactly equal to ). According to the special theory of relativity, is the upper limit fo ...
. The kinetic energies E_ of the positron and electron relate to their total energies E_ and
momenta Momenta is an autonomous driving company headquartered in Beijing, China that aims to build the 'Brains' for autonomous vehicles. In December 2021, Momenta and BYD established a 100 million yuan ($15.7 million) joint venture to deploy autonomous ...
\mathbf_ via E_=E_+m_e c^2=\sqrt.
Conservation of energy In physics and chemistry, the law of conservation of energy states that the total energy of an isolated system remains constant; it is said to be ''conserved'' over time. This law, first proposed and tested by Émilie du Châtelet, means tha ...
yields \hbar\omega=E_+E_. The momentum \mathbf of the
virtual photon A virtual particle is a theoretical transient particle that exhibits some of the characteristics of an ordinary particle, while having its existence limited by the uncertainty principle. The concept of virtual particles arises in the perturb ...
between incident photon and nucleus is: \begin -\mathbf^2&=-, \mathbf_+, ^2-, \mathbf_-, ^2-\left(\frac\omega\right)^2+2, \mathbf_+, \frac \omega\cos\Theta_+ +2, \mathbf_-, \frac \omega\cos\Theta_- \\ &-2, \mathbf_+, , \mathbf_-, (\cos\Theta_+\cos\Theta_-+\sin\Theta_+\sin\Theta_-\cos\Phi), \end where the directions are given via: \begin \Theta_+&=\sphericalangle(\mathbf_+,\mathbf),\\ \Theta_-&=\sphericalangle(\mathbf_-,\mathbf),\\ \Phi&=\text (\mathbf_+,\mathbf) \text (\mathbf_-,\mathbf), \end where \mathbf is the momentum of the incident photon. In order to analyse the relation between the photon energy E_+ and the emission angle \Theta_+ between photon and positron, Köhn and Ebert integrated Koehn, C., Ebert, U., Angular distribution of Bremsstrahlung photons and of positrons for calculations of terrestrial gamma-ray flashes and positron beams, Atmos. Res. (2014), vol. 135-136, pp. 432-465 the quadruply differential cross section over \Theta_- and \Phi . The double differential cross section is: \begin \frac = \sum\limits_^ I_j \end with \begin I_1&=\frac \\ &\times \ln\left(\frac\right) \\ &\times\left 1-\frac+\frac -\frac\right \\ I_2&=\frac\ln\left( \frac\right), \\ I_3&=\frac \\ &\times\ln\Bigg(\Big((E_-+p_-c)(4p_+^2p_-^2\sin^2\Theta_+(E_--p_-c)+(\Delta^_1+\Delta^_2) ((\Delta^_2E_-+\Delta^_1p_-c) \\ &-\sqrt))\Big)\Big((E_--p_-c) (4p_+^2p_-^2\sin^2\Theta_+(-E_--p_-c) \\ &+(\Delta^_1-\Delta^_2) ((\Delta^_2E_-+\Delta^_1p_-c)-\sqrt))\Big)^\Bigg) \\ &\times\left frac\right.\\ &+\Big[((\Delta^_2)^2+4p_+^2p_-^2\sin^2\Theta_+)(E_-^3+E_-p_-c)+p_-c(2 ((\Delta^_1)^2-4p_+^2p_-^2\sin^2\Theta_+)E_-p_-c \\ &+\Delta^_1\Delta^_2(3E_-^2+p_-^2c^2))\BigBig[(\Delta^_2E_-+\Delta^_1p_-c)^2+4m^2c^4p_+^2p_-^2\sin^2\Theta_+\Big]^ \\ &+\Big[-8p_+^2p_-^2m^2c^4\sin^2\Theta_+(E_+^2+E_-^2)-2\hbar^2\omega^2p_+^2\sin^2\Theta_+p_-c(\Delta^_2E_-+\Delta^_1p_-c) \\ &+2\hbar^2\omega^2p_- m^2c^3(\Delta^_2E_-+\Delta^_1p_-c)\Big] \Big[(E_+-cp_+\cos\Theta_+)((\Delta^_2E_-+\Delta^_1p_-c)^2+4m^2c^4p_+^2p_-^2\sin^2\Theta_+)\Big]^ \\ &+\left.\frac\right], \\ I_4&=\frac+\frac, \\ I_5&=\frac \\ &\times\left frac \Big[E_-[2(\Delta^_2)^2((\Delta^_2)^2-(\Delta^_1)^2)+8p_+^2p_-^2\sin^2\Theta_+((\Delta^_2)^2+(\Delta^_1)^2)\right.\\ &+p_-c[2\Delta^_1\Delta^_2((\Delta^_2)^2-(\Delta^_1)^2)+16\Delta^_1\Delta^_2p_+^2p_-^2\sin^2\Theta_+]\Big]\Big[(\Delta^_2)^2+4p_+^2p_-^2\sin^2\Theta_+\Big]^\\ &+ \frac\\ &-\Big[2E_+^2p_-^2\\Big]\Big[(\Delta^_2E_-+\Delta^_1p_-c)^2+4m^2c^4p_+^2p_-^2\sin^2\Theta_+\Big]^\\ &-\left.\frac\right], \\ I_6&=-\frac \end and \begin A&=\frac\frac,\\ \Delta^_1&:=-, \mathbf_+, ^2-, \mathbf_-, ^2-\left(\frac\omega\right) + 2\frac\omega, \mathbf_+, \cos\Theta_+,\\ \Delta^_2&:=2\frac\omega, \mathbf_i, -2, \mathbf_+, , \mathbf_-, \cos\Theta_+ + 2. \end This cross section can be applied in Monte Carlo simulations. An analysis of this expression shows that positrons are mainly emitted in the direction of the incident photon.


References

{{Reflist Quantum mechanics Particle physics