Borexino

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Borexino neutrino observatory
Borexino Detector in LNGS in September 2015
Borexino from the North side of LNGS's underground Hall C in September 2015. It is shown close to being completely covered in thermal insulation (seen as a silvery wrapping) as an effort to further improve its unprecedented radiopurity levels.
Detector characteristics
LocationLaboratori Nazionali del Gran Sasso
Start of data-taking2007
Detection techniqueElastic scattering on liquid scintillator (PC+PPO)
Height16.9 m
Width18 m
Active mass(volume)278 tonnes (315 m3) ≈100 tonnes fiducial

Borexino is a particle physics experiment to study low energy (sub-MeV) solar neutrinos. The detector is the world's most radio-pure liquid scintillator calorimeter. It is placed within a stainless steel sphere which holds the photomultiplier tubes (PMTs) used as signal detectors and is shielded by a water tank to protect it against external radiation and tag incoming cosmic muons that manage to penetrate the overburden of the mountain above.

The primary aim of the experiment is to make a precise measurement of the individual neutrino fluxes from the Sun and compare them to the Standard solar model predictions. This will allow scientists to test and to further understand the functioning of the Sun (e.g., nuclear fusion processes taking place at the core of the Sun, solar composition, opacity, matter distribution, etc.) and will also help determine properties of neutrino oscillations, including the MSW effect. Specific goals of the experiment are to detect beryllium-7, boron-8, pp, pep and CNO solar neutrinos as well as anti-neutrinos from the Earth and nuclear power plants. The project may also be able to detect neutrinos from supernovae within our galaxy with a special potential to detect the elastic scattering of neutrinos onto protons, due to neutral current interactions. Borexino is a member of the Supernova Early Warning System.[1] Searches for rare processes and potential unknown particles are also underway.

The name Borexino is the Italian diminutive of BOREX (Boron solar neutrino Experiment), after the original 1 kT-fiducial experimental proposal with a different scintillator (TMB), was discontinued because of a shift in focus in physics goals as well as financial constraints.[2] The experiment is located at the Laboratori Nazionali del Gran Sasso near the town of L'Aquila, Italy, and is supported by an international collaboration with researchers from Italy, the United States, Germany, France, Poland, Russia and Ukraine.[3] The experiment is funded by multiple national agencies; the principal ones are INFN (National Institute for Nuclear Physics, Italy) and NSF (National Science Foundation, USA). In May 2017, Borexino reached 10 years of continuous operation since the start of its data-taking period in 2007.

The SOX experiment was a sub-project designed to study the possible existence of sterile neutrinos or other anomalous effects in neutrino oscillations at short ranges through the use of a neutrino generator based on radioactive cerium-144 placed right under the water tank of the Borexino detector. This project was cancelled in early 2018 due to insurmountable technical problems in the fabrication of the antineutrino source.

Results and detector timeline[]

  • 1986 initial BOREX proposal (R. Raghavan et al).[2]
  • 1990 design (and name) change, Borexino R&D begins.[2]
  • 2004 detector structure construction completed.[3]
  • As of May 2007 filling operations was completed and the Borexino detector started taking data.[3][4]
  • In August 2007 the collaboration published the first results: “First real time detection of 7Be solar neutrinos by Borexino”.[5][6] The subject was further extended in 2008.[7]
  • In 2010, "geoneutrinos" from Earth's interior were observed for the first time in Borexino. These are anti-neutrinos produced in radioactive decays of uranium, thorium, potassium, and rubidium, although only the anti-neutrinos emitted in the 238U/232Th chains are visible because of the inverse beta decay reaction channel Borexino is sensitive to.[8][9] That year, the lowest-threshold (3 MeV) measurement of the 8B solar neutrino flux was also published.[10] Additionally, a multi-source detector calibration campaign took place,[11] where several radioactive sources were inserted in the detector to study its response to known signals which are close to the expected ones to be studied.
  • The gray bands compare the regions where the three solar neutrino telescopes, that are able to measure the energy of the events, are sensitive. Note that the predictions of solar models are in logarithmic scale: Super-Kamiokande and SNO can observe about 0.02% of the total, while Borexino may observe each type of predicted neutrino.
    In 2011, the experiment published a precision measurement of the beryllium-7 neutrino flux,[12][13] as well as the first evidence for the pep solar neutrinos.[14][15]
  • In 2012, they published the results of measurements of the speed of CERN Neutrinos to Gran Sasso. The results were consistent with the speed of light.[16] See measurements of neutrino speed. An extensive scintillator purification campaign was also performed, achieving the successful goal of further reducing the residual background radioactivity levels to unprecedented low amounts (up to 15 orders of magnitude under natural background radioactivity levels).
  • In 2013, Borexino set a limit on sterile neutrino parameters.[17] They also extracted a signal of geoneutrinos,[18] which gives insight into radioactive element activity in the earth's crust,[19] a hitherto unclear field.[20]
  • In 2014, the experimental collaboration published an analysis of the proton–proton fusion activity in the solar core, finding solar activity has been consistently stable on a 105-year scale.[21][22] Once the phenomenon of neutrino oscillations, as described by MSW theory, is considered, the measurement of Borexino is consistent with the expectations from the standard solar model. The result of Borexino is a milestone in our understanding of the functioning of the Sun. The previous experiments sensitive to low energy neutrinos (SAGE, Gallex, GNO) have succeeded to count the neutrinos above a certain energy, but did not measure the individual fluxes.
    Spectrum of the Borexino data used for the simultaneous determination of the pp, pep and 7Be solar ν fluxes, as well as the best available limit on CNO ν flux with weak constraints.[23] Solar ν components are shown in red; background components in other colors. The lower plot shows the difference between the spectral shape of the data (black curve), and the expected shape when analytically adding together and fitting the signals corresponding to each species.
  • In 2015, an updated spectral analysis of geoneutrinos was presented,[24] and the world best limit on the electric charge non-conservation was set.[25] Additionally, a versatile Temperature Management and Monitoring System was installed in several phases throughout 2015.[26] It consists of the multi-sensor Latitudinal Temperature Probe System (LTPS), whose testing and first-phase installation occurred in late 2014; and the Thermal Insulation System (TIS), that minimized the thermal influence of the exterior environment on the interior fluids[27] through the extensive insulation of the experiment's external walls. Later in 2015, Borexino also yielded the best available limit to the lifetime of the electron (via e→γ+ν decay), providing the most stringent confirmation of charge conservation to date.

SOX project[]

SOX antineutrino generator deployment along rail tracks: from its external dropoff point (lower right), through the calorimetry areas (lower right inside clean room), to its operational position (top center) in the small pit under Borexino

The SOX experiment[32] aimed at the complete confirmation or at a clear disproof of the so-called neutrino anomalies, a set of circumstantial evidences of electron neutrino disappearance observed at LSND, MiniBooNE, with nuclear reactors and with solar neutrino Gallium detectors (GALLEX/GNO, SAGE). If successful, SOX would demonstrate the existence of sterile neutrino components and open a brand new era in fundamental particle physics and cosmology. A solid signal would mean the discovery of the first particles beyond the Standard Electroweak Model and would have profound implications in our understanding of the Universe and of fundamental particle physics. In case of a negative result, it would be able to close a long-standing debate about the reality of the neutrino anomalies, would probe the existence of new physics in low energy neutrino interactions, would provide a measurement of neutrino magnetic moment, Weinberg angle and other basic physical parameters; and would yield a superb energy calibration for Borexino which will be very beneficial for future high-precision solar neutrino measurements.

SOX was envisioned to use a powerful (≈150 kCi) and innovative antineutrino generator made of Ce-144/Pr-144 and possibly a later Cr-51 neutrino generator, which would require a much shorter data-taking campaign. These generators would be located at short distance (8.5 m) from the Borexino detector -under it, in fact: in a pit built ex-profeso before the detector was erected, with the idea it could be used for the insertion of such radioactive sources- and would yield tens of thousands of clean neutrino interactions in the internal volume of the Borexino detector. A high precision (<1% uncertainty) twin-calorimetry campaign would be carried out before deployment in the pit, at the end of data-taking and possibly at some point during the experimental run, in order to provide an independent precise measurement of the source's activity, in order to accomplish a low-uncertainty rate analysis. Shape analyses for the source's antineutrino signal have also been developed in order to increase the experiment's sensitivity, covering the whole high-significance "anomaly" phase space that is still left where light sterile neutrinos could lie in.

SOX cancelled[]

The experiment was expected to start in the first half of 2018 and take data for about two years. In October 2017, an end-to-end "blank" (without radioactive material) transport test was carried out successfully at the Borexino site in LNGS,[33] in order to clear out final regulatory permissions for the start of the experiment, ahead of the arrival of the source. The cerium oxide (ceria, or CeO2) source for CeSOX's antineutrino generator had to be manufactured by Mayak PA, but technical problems during the fabrication were disclosed in late 2017. These problems meant the generator would not be able to provide the necessary amount of antineutrinos,[34] by a factor of 3, and prompted a review of the project and its eventual starting date. By early February 2018, the CeSOX project was officially cancelled by CEA and INFN due to the radioactive source production problem,[35] and Borexino's 2018-19 goals were reoriented toward achieving higher detector stability and, with it, increased radiopurity, in order to push for higher precision solar neutrino results, with special emphasis on CNO neutrinos.

References[]

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  2. ^ a b c Georg G. Raffelt (1996). "BOREXINO". Stars As Laboratories for Fundamental Physics: The Astrophysics of Neutrinos, Axions, and Other Weakly Interacting Particles. University of Chicago Press. pp. 393–394. ISBN 978-0226702728.
  3. ^ a b c "Borexino Experiment Official Website".
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  5. ^ Emiliano Feresin (2007). "Low-energy neutrinos spotted". Nature News. doi:10.1038/news070820-5. S2CID 119468807.
  6. ^ Borexino Collaboration (2008). "First real time detection of 7Be solar neutrinos by Borexino". Physics Letters B. 658 (4): 101–108. arXiv:0708.2251. Bibcode:2008PhLB..658..101B. doi:10.1016/j.physletb.2007.09.054.
  7. ^ Borexino Collaboration (2008). "Direct Measurement of the Be7 Solar Neutrino Flux with 192 Days of Borexino Data". Physical Review Letters. 101 (9): 091302. arXiv:0805.3843. Bibcode:2008PhRvL.101i1302A. doi:10.1103/PhysRevLett.101.091302. PMID 18851600.
  8. ^ "A first look at the Earth interior from the Gran Sasso underground laboratory". INFN press release. 11 March 2010.
  9. ^ Borexino Collaboration (2010). "Observation of geo-neutrinos". Physics Letters B. 687 (4–5): 299–304. arXiv:1003.0284. Bibcode:2010PhLB..687..299B. doi:10.1016/j.physletb.2010.03.051.
  10. ^ Borexino Collaboration; Bellini, G.; Benziger, J.; Bonetti, S.; Buizza Avanzini, M.; Caccianiga, B.; Cadonati, L.; Calaprice, F.; Carraro, C. (2010-08-05). "Measurement of the solar $^{8}\mathrm{B}$ neutrino rate with a liquid scintillator target and 3 MeV energy threshold in the Borexino detector". Physical Review D. 82 (3): 033006. arXiv:0808.2868. Bibcode:2010PhRvD..82c3006B. doi:10.1103/PhysRevD.82.033006. S2CID 119258273.
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  12. ^ "Precision measurement of the beryllium solar neutrino flux and its day/night asymmetry, and independent validation of the LMA-MSW oscillation solution using Borexino-only data". Borexino Collaboration press release. 11 April 2011.
  13. ^ Borexino Collaboration (2011). "Precision Measurement of the Be7 Solar Neutrino Interaction Rate in Borexino". Physical Review Letters. 107 (14): 141302. arXiv:1104.1816. Bibcode:2011PhRvL.107n1302B. doi:10.1103/PhysRevLett.107.141302. PMID 22107184.
  14. ^ "Borexino Collaboration succeeds in spotting pep neutrinos emitted from the sun". PhysOrg.com. 9 February 2012.
  15. ^ Borexino Collaboration (2012). "First Evidence of pep 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. S2CID 118444784.
  16. ^ Borexino collaboration (2012). "Measurement of CNGS muon neutrino speed with Borexino". Physics Letters B. 716 (3–5): 401–405. arXiv:1207.6860. Bibcode:2012PhLB..716..401A. doi:10.1016/j.physletb.2012.08.052. hdl:11696/50952.
  17. ^ Bellini, G.; Benziger, J.; Bick, D.; Bonfini, G.; Bravo, D.; Buizza Avanzini, M.; Caccianiga, B.; Cadonati, L.; Calaprice, F. (2013-10-29). "New limits on heavy sterile neutrino mixing in B 8 decay obtained with the Borexino detector". Physical Review D. 88 (7): 072010. arXiv:1311.5347. Bibcode:2013PhRvD..88g2010B. doi:10.1103/physrevd.88.072010. ISSN 1550-7998. S2CID 27175903.
  18. ^ Borexino Collaboration (15 April 2013). "Measurement of geo-neutrinos from 1353 days of Borexino". Phys. Lett. B. 722 (4–5): 295–300. arXiv:1303.2571. Bibcode:2013PhLB..722..295B. doi:10.1016/j.physletb.2013.04.030. S2CID 55822151.
  19. ^ "Borexino has new results on geoneutrinos". CERN COURIER. Retrieved 20 October 2014.
  20. ^ Šrámek, Ondřej; Roskovec, Bedřich; Wipperfurth, Scott A.; Xi, Yufei; McDonough, William F. (2016). "Revealing the Earth's mantle from the tallest mountains using the Jinping Neutrino Experiment". Scientific Reports. 6: 33034. Bibcode:2016NatSR...633034S. doi:10.1038/srep33034. PMC 5017162. PMID 27611737.
  21. ^ 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.
  22. ^ "Borexino measures the Sun's energy in real time". CERN COURIER. Retrieved 20 October 2014.
  23. ^ Agostini, M; et al. (Borexino) (2019). "First Simultaneous Precision Spectroscopy of pp, 7Be, and pep Solar Neutrinos with Borexino Phase-II". Phys. Rev. D. 100: 082004. arXiv:1707.09279. doi:10.1103/PhysRevD.100.082004. S2CID 118938742.
  24. ^ Borexino Collaboration (7 August 2015). "Spectroscopy of geoneutrinos from 2056 days of Borexino data". Phys. Rev. D. 92 (3): 031101. arXiv:1506.04610. Bibcode:2015PhRvD..92c1101A. doi:10.1103/PhysRevD.92.031101. S2CID 55041121.
  25. ^ Agostini, M.; et al. (Borexino Collaboration) (2015). "Test of Electric Charge Conservation with Borexino". Physical Review Letters. 115 (23): 231802. arXiv:1509.01223. Bibcode:2015PhRvL.115w1802A. doi:10.1103/PhysRevLett.115.231802. PMID 26684111. S2CID 206265225.
  26. ^ Bravo-Berguño, David; Mereu, Riccardo; Cavalcante, Paolo; Carlini, Marco; Ianni, Andrea; Goretti, Augusto; Gabriele, Federico; Wright, Tristan; Yokley, Zachary (2017-05-25). "The Borexino Thermal Monitoring and Management System". arXiv:1705.09078 [physics.ins-det].
  27. ^ Bravo-Berguño, David; Mereu, Riccardo; Vogelaar, Robert Bruce; Inzoli, Fabio (2017-05-26). "Fluid-dynamics in the Borexino Neutrino Detector: behavior of a pseudo-stably-stratified, near-equilibrium closed system under asymmetrical, changing boundary conditions". arXiv:1705.09658 [physics.ins-det].
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  29. ^ The Borexino Collaboration; Agostini, M.; Altenmueller, K.; Appel, S.; Atroshchenko, V.; Bagdasarian, Z.; Basilico, D.; Bellini, G.; Benziger, J. (2020). "Improved measurement of 8B solar neutrinos with 1.5 kt y of Borexino exposure". Phys. Rev. D. 101 (6): 062001. arXiv:1709.00756. Bibcode:2020PhRvD.101f2001A. doi:10.1103/PhysRevD.101.062001. S2CID 119348649.
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  32. ^ Caminata, Alessio. "The SOX project". web.ge.infn.it. Archived from the original on 2017-10-19. Retrieved 2016-04-22.
  33. ^ Galeota, Marco. "Il test di trasporto per l'esperimento SOX". Laboratori Nazionali del Gran Sasso (in Italian). Retrieved 2017-10-25.
  34. ^ Galeota, Marco. "Nota stampa 12-12-2017". Laboratori Nazionali del Gran Sasso (in Italian). Retrieved 2017-12-13.
  35. ^ varaschin. "THE SOX PROJECT IS CANCELLED DUE TO THE IMPOSSIBILITY OF REALIZING THE SOURCE WITH THE REQUIRED CHARACTERISTICS". home.infn.it. Archived from the original on 2018-03-09. Retrieved 2018-03-16.

External links[]

Coordinates: 42°28′N 13°34′E / 42.46°N 13.57°E / 42.46; 13.57

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