Inverse beta decay

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In nuclear and particle physics, inverse beta decay, commonly abbreviated to IBD,^[1] is a nuclear reaction involving an electron antineutrino scattering off a proton, creating a positron and a neutron. This process is commonly used in the detection of electron antineutrinos in neutrino detectors, such as the first detection of antineutrinos in the Cowan–Reines neutrino experiment, or in neutrino experiments such as KamLAND and Borexino. It is an essential process to experiments involving low-energy neutrinos (< 60 MeV)^[2] such as those studying neutrino oscillation,^[2] reactor neutrinos, sterile neutrinos, and geoneutrinos.^[3]

Inverse beta decay proceeds as^[2][3][4]

Template:Subatomic particle + Template:Subatomic particle → Template:Subatomic particle + Template:Subatomic particle,

where an electron antineutrino (Template:Subatomic particle) interacts with a proton (Template:Subatomic particle) to produce a positron (Template:Subatomic particle) and a neutron (Template:Subatomic particle). The IBD reaction can only be initiated when the antineutrino possesses at least 1.806 MeV^[3][4] of kinetic energy (called the threshold energy). This threshold energy is due to a difference in mass between the products (Template:Subatomic particle and Template:Subatomic particle) and the reactants (Template:Subatomic particle and Template:Subatomic particle) and also slightly due to a relativistic mass effect on the antineutrino. Most of the antineutrino energy is distributed to the positron due to its small mass relative to the neutron. The positron promptly^[4] undergoes matter–antimatter annihilation after creation and yields a flash of light with energy calculated as^[5]

$${\displaystyle \begin{array}{cc}{E}_{\text{vis}}& =511\text{ keV}+511\text{ keV}+E_{{\bar{\mathrm{\nu }}}_{\mathrm{e}}}-1806\text{ keV}\\ & =E_{{\bar{\mathrm{\nu }}}_{\mathrm{e}}}-784\text{ keV}\end{array}}$$

where 511 keV is the electron and positron rest energy, Template:Math is the visible energy from the reaction, and Template:Tmath is the antineutrino kinetic energy. After the prompt positron annihilation, the neutron undergoes neutron capture on an element in the detector, producing a delayed flash of 2.22 MeV if captured on a proton.^[4] The timing of the delayed capture is 200–300 microseconds after IBD initiation (Template:Val in the Borexino detector^[4]). The timing and spatial coincidence between the prompt positron annihilation and delayed neutron capture provides a clear IBD signature in neutrino detectors, allowing for discrimination from background.^[4] The IBD cross section is dependent on antineutrino energy and capturing element, although is generally on the order of 10⁻⁴⁴ cm² (~ attobarns).^[6]

Another kind of inverse beta decay is the reaction

Template:Subatomic particle + Template:Subatomic particle → Template:Subatomic particle + Template:Subatomic particle

The Homestake experiment used the reaction

${\displaystyle {\mathrm{\nu }}_{\mathrm{e}}\mathrm{+}{}^{\mathrm{3}\mathrm{7}}\mathrm{C}\mathrm{l}\mathrm{⟶}{}^{\mathrm{3}\mathrm{7}}\mathrm{A}\mathrm{r}\mathrm{+}{\mathrm{e}}^{\mathrm{-}}}$

to detect solar neutrinos.

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During the formation of neutron stars, or in radioactive isotopes capable of electron capture, neutrons are created by electron capture:

Template:Subatomic particle + Template:Subatomic particle → Template:Subatomic particle + Template:Subatomic particle.

This is similar to the inverse beta reaction in that a proton is changed to a neutron, but is induced by the capture of an electron instead of an antineutrino.

• Kamioka Liquid Scintillator Antineutrino Detector

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