Solar neutrino: Difference between revisions

Solar neutrinos (proton-proton chain) in the Standard Solar Model

Electron neutrinos are produced in the Sun as a product of nuclear fusion. Solar neutrinos constitute by far the largest flux of neutrinos from natural sources observed on Earth, as compared with e.g. atmospheric neutrinos or the diffuse supernova neutrino background.^[1]

Production mechanisms

Solar Neutrino Generation

Solar neutrinos are produced in the core of the Sun through various nuclear fusion reactions, each of which occurs at a particular rate and leads to its own spectrum of neutrino energies. Details of the more prominent of these reactions are described below.

The main contribution comes from the proton-proton reaction. The reaction is:

${\displaystyle {\text{p}}+{\text{p}}\to {\text{d}}+{\text{e}}^{+}+\operatorname {\nu } _{\text{e}}}$

or in words:

two protons ${\displaystyle \to }$ deuteron + positron + electron neutrino.

Of all Solar neutrinos, approximately 91% are produced from this reaction.^[2] As shown in the figure titled "Solar neutrinos (proton-proton chain) in the Standard Solar Model", the deuteron will fuse with another proton to create a ³He nucleus and a gamma ray. This reaction can be seen as:

${\displaystyle {\text{d}}+{\text{p}}\to {^{3}}{\text{He}}+\operatorname {\gamma } }$

The isotope ⁴He can be produced by using the ³He in the previous reaction which is seen below.

${\displaystyle {^{3}}{\text{He}}+{^{3}}{\text{He}}\to {^{4}}{\text{He}}+2\,{\text{p}}}$

With both helium-3 and helium-4 now in the environment, one of each weight of helium nucleus can fuse to produce beryllium:

${\displaystyle {^{3}}{\text{He}}+{^{4}}{\text{He}}\to {^{7}}{\text{Be}}+\operatorname {\gamma } }$

Beryllium-7 can follow two different paths from this stage: It could capture an electron and produce the more stable lithium-7 nucleus and an electron neutrino, or alternatively, it could capture one of the abundant protons, which would create boron-8. The first reaction via lithium-7 is:

${\displaystyle {^{7}}{\text{Be}}+{\text{e}}^{-}\to {^{7}}{\text{Li}}+\operatorname {\nu } _{\text{e}}}$

This lithium-yielding reaction produces approximately 7% of the solar neutrinos.^[2] The resulting lithium-7 later combines with a proton to produce two nuclei of helium-4. The alternative reaction is proton capture, that produces boron-8, which then beta⁺ decays into beryllium-8 as shown below:

${\displaystyle {^{7}}{\text{Be}}+{\text{p}}\to {^{8}}{\text{B}}+\operatorname {\gamma } }$

${\displaystyle {^{8}}{\text{B}}\to {^{8}}{\text{Be}}{^{*}}+{\text{e}}^{+}+\operatorname {\nu } _{\text{e}}}$

This alternative boron-yielding reaction produces about 0.02% of the solar neutrinos; although so few that they would conventionally be neglected, these rare solar neutrinos stand out because of their higher average energies. The asterisk (*) on the beryllium-8 nucleus indicates that it is in an excited, unstable state. The excited beryllium-8 nucleus then splits into two helium-4 nuclei:^[3]

${\displaystyle {^{8}}{\text{Be}}{^{*}}\to {^{4}}{\text{He}}+{^{4}}{\text{He}}}$

Observed data

The greatest number of solar neutrinos are direct products of the proton-proton reaction (tall, dark blue curve on the left). They have a low energy – only reaching up to 400 keV. There are several other significant production mechanisms, with energies up to 18 MeV.^[4]

The highest flux of solar neutrinos come directly from the proton-proton interaction, and have a low energy, up to 400 keV. There are also several other significant production mechanisms, with energies up to 18 MeV.^[4] From the Earth, the amount of neutrino flux at Earth is around 7·10¹⁰ particles·cm⁻²·s ⁻¹.^[5] The number of neutrinos can be predicted with great confidence by the Standard Solar Model. However, the number of electron neutrinos detected on Earth was only 1/3 of the predicted number, and this was known as the “solar neutrino problem”.

The absence of electron neutrinos, and the fact that it is one of three known types of neutrino, eventually prompted the idea of neutrino oscillation and the fact that neutrinos can change flavour. This was confirmed when the total flux of solar neutrinos of all types was measured and it agreed with the earlier predictions of the expected flux of only electron neutrinos, as seen by Sudbury Neutrino Observatory. The fact that the electron neutrinos could spontaneously change in flight through empty space also confirmed that neutrinos must have mass. Solar models additionally predict the location within the Sun's core where solar neutrinos should originate from, depending on the nuclear fusion reaction which leads to their production. Future neutrino detectors will be able to detect the incoming direction of these neutrinos with enough precision to measure this effect.^[6]

Theoretical curves of survival probability of solar neutrinos that arrive on day (orange, continuous) or on night (purple, dashed), as a function of the energy of the neutrinos. Also shown the four values of the energy of the neutrinos at which measurements have been performed, corresponding to four different branches of the proton-proton chain.

The energy spectrum of solar neutrinos is also predicted by solar models.^[7] It is essential to know this energy spectrum because different neutrino detection experiments are sensitive to different neutrino energy ranges. The Homestake Experiment used chlorine and was most sensitive to solar neutrinos produced by the decay of the beryllium isotope ⁷Be. The Sudbury Neutrino Observatory is most sensitive to solar neutrinos produced by ⁸B. The detectors that use gallium are most sensitive to the solar neutrinos produced by the proton-proton chain reaction process, however they were not able to observe this contribution separately. The observation of the neutrinos from the basic reaction of this chain, proton-proton fusion in deuterium, was achieved for the first time by Borexino in 2014. In 2012 the same collaboration reported detecting low-energy neutrinos for the proton-electron-proton (pep reaction) that produces 1 in 400 deuterium nuclei in the sun.^[8][9] The detector contained 100 metric tons of liquid and saw on average 3 events each day (due to ¹¹C production) from this relatively uncommon thermonuclear reaction. In 2014, Borexino reported a successful direct detection of neutrinos from the pp-reaction at a rate of 144±33/day, consistent with the predicted rate of 131±2/day that was expected based on the Standard Solar Model prediction that the pp-reaction generates 99% of the Sun's luminosity and their analysis of the detector's efficiency.^{[10] [11]} And in 2020, Borexino reported the first detection of CNO cycle neutrinos from deep within the solar core.^[12]

Note that Borexino measured neutrinos of several energies; in this manner they have demonstrated experimentally, for the first time, the pattern of solar neutrino oscillations predicted by the theory. Neutrinos can trigger nuclear reactions. By looking at ancient ores of various ages that have been exposed to solar neutrinos over geologic time, it may be possible to interrogate the luminosity of the Sun over time,^[13] which, according to the Standard Solar Model, has changed over the eons as the (presently) inert byproduct helium has accumulated in its core.

See also

• Neutrino oscillations
• Solar neutrino problem
• Neutrino detector
• Neutral particle oscillation
• Solar neutrino unit
• Stellar nucleosynthesis

References

1. Billard, J.; Strigari, L.; Figueroa-Feliciano, E. (2014). "Implication of neutrino backgrounds on the reach of next generation dark matter direct detection experiments". Phys. Rev. D. 89 (2): 023524. arXiv:1307.5458. Bibcode:2014PhRvD..89b3524B. doi:10.1103/PhysRevD.89.023524.
2. https://iopscience.iop.org/article/10.3847/1538-4357/835/2/202
3. Grupen, Claus (2005). Astroparticle Physics. Springer. ISBN 978-3-540-25312-9.^{[page needed]}
4. Bellerive, A. (2004). "Review of solar neutrino experiments". International Journal of Modern Physics A. 19 (8): 1167–1179. arXiv:hep-ex/0312045. Bibcode:2004IJMPA..19.1167B. doi:10.1142/S0217751X04019093.
5. Grupen 2005, p. 95
6. Davis, Jonathan H. (2016). "Projections for measuring the size of the solar core with neutrino-electron scattering". Physical Review Letters. 117 (21): 211101. arXiv:1606.02558. Bibcode:2016PhRvL.117u1101D. doi:10.1103/PhysRevLett.117.211101. PMID 27911522.
7. "Solar neutrino viewgraphs". www.sns.ias.edu.
8. Bellini, G.; et al. (2012). "First evidence of p-e-p solar neutrinos by direct detection in Borexino". Physical Review Letters. 108 (5): 051302. arXiv:1110.3230. Bibcode:2012PhRvL.108e1302B. doi:10.1103/PhysRevLett.108.051302. PMID 22400925. 051302.. 6 pages; preprint on arXiv
9. Witze, Alexandra (10 March 2012). "Elusive solar neutrinos spotted, detection reveals more about reaction that powers sun". Science News. Vol. 181, no. 5. p. 14. doi:10.1002/scin.5591810516.
10. Borexino Collaboration (27 August 2014). "Neutrinos from the primary proton–proton fusion process in the Sun". Nature. 512 (7515): 383–386. Bibcode:2014Natur.512..383B. doi:10.1038/nature13702. PMID 25164748. S2CID 205240340.
11. "Borexino measures the Sun's energy in real time". CERN COURIER. Retrieved 20 October 2014.
12. Agostini, M.; Altenmüller, K.; Appel, S.; Atroshchenko, V.; Bagdasarian, Z.; Basilico, D.; Bellini, G.; Benziger, J.; Biondi, R.; Bravo, D.; Caccianiga, B. (November 2020). "Experimental evidence of neutrinos produced in the CNO fusion cycle in the Sun". Nature. 587 (7835): 577–582. Bibcode:2020Natur.587..577B. doi:10.1038/s41586-020-2934-0. ISSN 1476-4687. PMID 33239797.
13. Haxton, W.C. (1990). "Proposed neutrino monitor of long-term solar burning". Physical Review Letters. 65 (7): 809–812. Bibcode:1990PhRvL..65..809H. doi:10.1103/physrevlett.65.809. PMID 10043028.

Further reading

• Haxton, W.C.; Hamish Robertson, R.G.; Serenelli, Aldo M. (18 August 2013). "Solar Neutrinos: Status and Prospects". Annual Review of Astronomy and Astrophysics. 51 (1): 21–61. arXiv:1208.5723. Bibcode:2013ARA&A..51...21H. CiteSeerX 10.1.1.755.6940. doi:10.1146/annurev-astro-081811-125539.