T1 – HYPER KAMIOKANDE

Trumpet Number One

Appendix Six

HYPER KAMIOKANDE

More information can be found at this link https://en.wikipedia.org/wiki/Hyper-Kamiokande

Hyper-Kamiokande (also called Hyper-K or HK) is a neutrino observatory and experiment under construction in Hida, Gifu and in Tokai, Ibaraki in Japan. It is conducted by the University of Tokyo and the High Energy Accelerator Research Organization (KEK), in collaboration with institutes from over 20 countries across six continents.[1][2] As a successor of the Super-Kamiokande (also Super-K or SK) and T2K experiments, it is designed to search for proton decay and detect neutrinos from natural sources such as the Earth, the atmosphere, the Sun and the cosmos, as well as to study neutrino oscillations of the man-made accelerator neutrino beam.[3]: 6, 20–28  The beginning of data-taking is planned for 2027.

The Hyper-Kamiokande experiment facility will be located in two places:

The neutrino beam will be produced in the accelerator complex J-PARC (36.445°N 140.606°E) and studied by the set of near and intermediate detectors located in Tokai village, Ibaraki prefecture, on the east coast of Japan.[3]: 31 

The main detector, also called Hyper-Kamiokande (HK), is being constructed under the peak of Nijuugo Mountain in Hida city, Gifu Prefecture, in the Japanese Alps (36°21′20.105″N 137°18′49.137″E[3]: 56 ). The HK detector will be used for proton decay searches, studies of neutrinos from natural sources and will serve as a far detector for the measurement of the oscillations of an accelerator neutrino beam at the distance corresponding to the first oscillation maximum.[3]: 53–56 [5]

Physics program

Accelerator and atmospheric neutrino oscillations

Neutrino oscillations are a quantum mechanical phenomenon in which neutrinos change their flavour (neutrino flavours states:

while moving, caused by the fact that the neutrino flavour states are a mixture of the neutrino mass states (ν1, ν2, ν3 mass states with masses m1, m2, m3, respectively). The oscillation probabilities depend on the six theoretical parameters: three mixing angles (θ12, θ23 and θ13) governing the mixing between mass and flavour states,two mass squared differences (∆m221 and ∆m232, where ∆m2ij = m2i – m2j)one phase (δCP) responsible for the matter-antimatter asymmetry (CP symmetry violation) in neutrino oscillations,and two parameters which are chosen for a particular experiment:

neutrino energy

Continuing studies done by the T2K experiment, the HK far detector will measure the energy spectra of electron and muon neutrinos in the beam (produced at J-PARC as an almost pure muon neutrino beam) and compare it with the expectation in case of no oscillations, which is initially calculated based on neutrino flux and interaction models and improved by measurements performed by the near and intermediate detectors. For the HK/T2K neutrino beam peak energy (600 MeV) and the J-PARC – HK/SK detector distance (295 km), this corresponds to the first oscillation maximum, for oscillations driven by ∆m232. The J-PARC neutrino beam will run in both neutrino- and antineutrino-enhanced modes separately, meaning that neutrino measurements in each beam mode will provide information about muon (anti)neutrino survival probability allows measurement of the δCP phase. δCP ranges from −π to +π (from −180° to +180°), and 0 and ±π correspond to CP symmetry conservation. After 10 years of data taking, HK is expected to confirm at the 5σ confidence level or better if CP symmetry is violated in the neutrino oscillations for 57% of possible δCP values. CP violation is one of the conditions necessary to produce the excess of matter over antimatter at the early universe, which forms now our matter-built universe. Accelerator neutrinos will be used also to enhance the precision of the other oscillation parameters, |∆m232|, θ23 and θ13, as well as for neutrino interaction studies.[3]: 202–224 

In order to determine the neutrino mass ordering (whether the ν3 mass eigenstate is lighter or heavier than both ν1 and ν2), or equivalently the unknown sign of the ∆m232 parameter, neutrino oscillations must be observed in matter. With HK beam neutrinos (295 km, 600 MeV), the matter effect is small. In addition to beam neutrinos, the HK experiment studies atmospheric neutrinos, created by cosmic rays colliding with the Earth’s atmosphere, producing neutrinos and other byproducts. These neutrinos are produced at all points on the globe, meaning that HK has access to neutrinos that have travelled through a wide range of distances through matter (from a few hundred metres to the Earth’s diameter). These samples of neutrinos can be used to determine the neutrino mass ordering.[3]: 225–237 

Ultimately, a combined beam neutrino and atmospheric neutrino analysis will provide the most sensitivity to the oscillation parameters δCP, |∆m232|, sgn ∆m232, θ23 and θ13.[3]: 228–233 

Neutrino astronomy and geoneutrinos

Core-collapse supernova explosions produce great quantities of neutrinos. For a supernova in the Andromeda galaxy, 10 to 16 neutrino events are expected in the HK far detector. For a galactic supernova at a distance of 10 kpc about 50,000 to 94,000 neutrino interactions are expected during a few tens of seconds. For Betelgeuse at the distance 0.2 kpc, this rate could reach up to 108 interactions per second and such a high event rate was taken into account in the detector electronics and data acquisition (DAQ) system design, meaning that no data would be lost. Time profiles of the number of events registered in HK and their mean energy would enable testing models of the explosion. Neutrino directional information in the HK far detector can provide an early warning for the electromagnetic supernova observation, and can be used in other multi-messenger observations.[3]: 263–280 [7]

Neutrinos cumulatively produced by supernova explosions throughout the history of the universe are called supernova relic neutrinos (SRN) or diffuse supernova neutrino background (DSNB) and they carry information about star formation history. Because of a low flux (few tens/cm2/sec.), they have not yet been discovered. With ten years of data taking, HK is expected to detect about 40 SRN events in the energy range 16–30 MeV.[3]: 276–280 [8]

For the solar

Search for a day-night asymmetry in the neutrino flux – resulting from different distances travelled in matter (during the night neutrinos additionally cross the Earth before entering the detector) and thus the different oscillation probabilities caused by the matter effect.

Measurement of the survival probability for neutrino energies between 2 and 7 MeV – i.e. between regions dominated by oscillations in vacuum and oscillations in matter, respectively – which is sensitive to new physics models, like sterile neutrinos or non-standard interactions. Comparison of the neutrino flux with the solar activity (e.g. the 11-year solar cycle).

Geoneutrinos are produced in decays of radionuclides inside the Earth. Hyper-Kamiokande geoneutrino studies will help assess the Earth’s core chemical composition, which is connected with the generation of the geomagnetic field.[3]: 292–293 

Proton decay

The decay of a free proton into lighter subatomic particles has never been observed, but it is predicted by some grand unified theories (GUT) and results from baryon number (B) violation. B violation is one of the conditions needed to explain the predominance of matter over antimatter in the universe.

Dark matter

Dark matter is a hypothetical, non-luminous form of matter proposed to explain numerous astronomical observations suggesting the existence of additional invisible mass in galaxies. If the dark matter particles interact weakly, they may produce neutrinos through annihilation or decay. Those neutrinos could be visible in the HK detector as an excess of neutrinos from the direction of large gravitational potentials such as the galactic centre, the Sun or the Earth, over an isotropic atmospheric neutrino background.[3]: 281–286 

Experiment description

The Hyper-Kamiokande experiment consists of an accelerator neutrino beamline, a set of near detectors, the intermediate detector and the far detector (also called Hyper-Kamiokande). The far detector by itself will be used for proton decay searches and studies of neutrinos from natural sources. All the above elements will serve for the accelerator neutrino oscillation studies. Before launching the HK experiment, the T2K experiment will finish data taking and HK will take over its neutrino beamline and set of near detectors, while the intermediate and the far detectors have to be constructed anew.[13]

Intermediate Water Cherenkov Detector

The Intermediate Water Cherenkov Detector (IWCD) will be located at a distance of around 750 metres (2,460 ft) from the neutrino production place. It will be a cylinder filled with water of 10 metres (33 ft) diameter and 50 metres (160 ft) height with a 10 metres (33 ft) tall structure instrumented with around 400 multi-PMT modules (mPMTs), each consisting of nineteen 8 centimetres (3.1 in) diameter PhotoMultiplier Tubes (PMTs) encapsulated in a water-proof vessel. The structure will be moved in a vertical direction by a crane system, providing measurements of neutrino interactions at different off-axis angles (angles to the neutrino beam centre), spanning from 1° at the bottom to 4° at the top, and thus for different neutrino energy spectra.[note 1]

Combining the results from different off-axis angles, it is possible to extract the results for nearly monoenergetic neutrino spectrum without relying on theoretical models of neutrino interactions to reconstruct neutrino energy. Usage of the same type of detector as the far detector with almost the same angular and momentum acceptance allows comparison of results from these two detectors without relying on detector response simulations. These two facts, independence from the neutrino interaction and detector response models, will enable HK to minimise systematic error in the oscillation analysis. Additional advantages of such a design of the detector is the possibility to search for sterile oscillation patterns for different off-axis angles and to obtain a cleaner sample of electron neutrino interactions, whose fraction is larger for larger off-axis angles.[3]: 47–50 [14][15][16][17]

Hyper-Kamiokande far detector

A schematic of the Hyper-Kamiokande Far Detector, a water Cherenkov detector

The Hyper-Kamiokande detector will be built 650 metres (2,130 ft) under the peak of Nijuugo Mountain in the Tochibora mine, 8 kilometres (5.0 mi) south from the Super-Kamiokande (SK) detector. Both detectors will be at the same off-axis angle (2.5°) to the neutrino beam centre and at the same distance (295 kilometres (183 mi)) from the beam production place in J-PARC.[note 2][3]: 35 [18]

3-inch PMT (Photomultiplier) and WLS (Wavelength-Shifting Fiber) plate for Hyper-Kamiokande Far Detector Outer Detector

HK will be a water Cherenkov detector, 5 times larger (258 kton of water) than the SK detector. It will be a cylindrical tank of 68 metres (223 ft) diameter and 71 metres (233 ft) height. The tank volume will be divided into the Inner Detector (ID) and the Outer Detector (OD) by a 60 cm-wide inactive cylindrical structure, with its outer edge positioned 1 meter away from vertical and 2 meters away from horizontal tank walls. The structure will optically separate ID from OD and will hold PhotoMultiplier Tubes (PMTs) looking both inwards to the ID and outwards to the OD.[18][19]

In the ID, there will be at least 20,000 50 centimetres (20 in) diameter PhotoMultiplier Tubes (PMT) of R12860 type by Hamamatsu Photonics and approximately 800 multi-PMT modules (mPMTs). Each mPMT module consists of nineteen 8 centimetres (3.1 in) diameter photomultiplier tubes encapsulated in a water-proof vessel. The OD will be instrumented with at least 3,600 8 centimetres (3.1 in) diameter PMTs coupled with 0.6×30×30 cm3 wavelength shifting (WLS) plates (plates will collect incident photons and transport them to their coupled PMT) and will serve as a veto[note 3] to distinguish interactions occurring inside from particles entering from the outside of the detector (mainly cosmic-ray muons).[18][19][17]

J-PARC neutrino beam Japan to Korea

HK detector construction began in 2020 and the start of data collection is expected in 2027.[3][4][13]: 24  Studies have also been undertaken on the feasibility and physics benefits of building a second, identical water-Cherenkov tank in South Korea around 1100 km from J-PARC, which would be operational 6 years after the first tank.[5][20]

History and schedule

The Hyper-Kamiokande detector construction schedule

A history of large water Cherenkov detectors in Japan, and long-baseline neutrino oscillation experiments associated with them, excluding HK:

1983-1996: Kamiokande (Kamioka Nucleon Decay Experiment), which main goal was proton decay searches (the Nobel Prize in Physics 2002 for Masatoshi Koshiba) – the predecessor of Super-Kamiokande[1]

1996–present: Super-Kamiokande experiment – the predecessor of the Hyper-Kamiokande experiment, studying neutrinos from natural sources and searching for proton decay (the Nobel Prize in Physics 2015 for Takaaki Kajita)[1]

1999–2004: K2K experiment – the predecessor of the T2K experiment

2010–present: T2K experiment – the predecessor of the Hyper-Kamiokande experiment, studying accelerator neutrino oscillations

A history of the Hyper-Kamiokande experiment:

September 1999: First ideas of the new experiment presented[21]

2000: The name “Hyper-Kamiokande” used for the first time[22]

September 2011: Submitting LOI[23]

January 2015: MoU for cooperation in the Hyper-Kamiokande project signed by two host institutions: ICRR and KEK. Formation of the Hyper-Kamiokande proto-collaboration[24][25]

May 2018: Hyper-Kamiokande Design Report[3]

September 2018: Seed funding from MEXT allocated in 2019[26]

February 2020: The project officially approved by the Japanese Diet[4]

June 2020: Formation of the Hyper-Kamiokande collaboration

May 2021: Start of the HK detector access tunnel excavation[27]

2021: Beginning of the photomultiplier tubes mass production[28]

February 2022: Completion of the access tunnel construction[29]

October 2023: Completion of the HK detector main cavern dome section[30]

2027: The expected beginning of data-taking[4]

See also

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Bibliography

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References

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  1. Jump up to:a b c “Hyper-Kamiokande website: Overview”.
  2. ^ “Hyper-Kamiokande website: Collaboration Institutes”.
  3. Jump up to:a b c d e f g h i j k l m n o p q r s t u Hyper-Kamiokande Proto-Collaboration (28 November 2018). “Hyper-Kamiokande Design Report”. arXiv:1805.04163 [physics.ins-det].
  4. Jump up to:a b c d “Kamioka Observatory website: The Hyper-Kamiokande project is officially approved”. Kamioka Observatory ICRR, The University of Tokyo. 12 February 2018.
  5. Jump up to:a b Francesca Di Lodovico (Queen Mary, U. of London) for the Hyper-Kamiokande collaboration (Sep 20, 2017). “The Hyper-Kamiokande Experiment”J. Phys. Conf. Ser888 (1): 012020. Bibcode:2017JPhCS.888a2020Ddoi:10.1088/1742-6596/888/1/012020.
  6. ^ Particle Data Group and Workman (August 2022). “Review of Particle Physics”Progress of Theoretical and Experimental Physics2022 (8): 083C01. doi:10.1093/ptep/ptac097hdl:11585/900713.
  7. ^ the Hyper-Kamiokande collaboration (Jan 13, 2021). “Supernova Model Discrimination with Hyper-Kamiokande”Astrophys. J916 (1): 15. arXiv:2101.05269Bibcode:2021ApJ…916…15Adoi:10.3847/1538-4357/abf7c4.
  8. ^ Yano, Takatomi (2021). “Prospects for neutrino astrophysics with Hyper-Kamiokande”PoS. ICRC2021: 1193. doi:10.22323/1.395.1193hdl:20.500.11850/589619.
  9. ^ Maltoni, Michele and Smirnov, Alexei Yu. (Jul 19, 2015). “Solar neutrinos and neutrino physics”Eur. Phys. J. A52 (4): 87. arXiv:1507.05287doi:10.1140/epja/i2016-16087-0S2CID 254115998.
  10. ^ “Hyper-Kamiokande website: Cosmic Neutrino Observation: Solar neutrinos”.
  11. ^ Mine, Shunichi (2023). “Nucleon decay: theory and experimental overview”. Zenododoi:10.5281/zenodo.10493165.
  12. ^ K. S. Babu; E. Kearns; et al. (2013-11-20). “Baryon Number Violation”. Proceedings, 2013 Community Summer Study on the Future of U.S. Particle Physics: Snowmass on the Mississippi (CSS2013). Minneapolis, MN, USA. arXiv:1311.5285.
  13. Jump up to:a b Vilela, Cristovao (September 5–10, 2021). “The status of T2K and Hyper-Kamiokande experiments”PANIC 2021 ConferenceArchived from the original on 2021-09-29. Retrieved 2021-09-29.
  14. ^ nuPRISM Collaboration (13 December 2014). “Letter of Intent to Construct a nuPRISM Detector in the J-PARC Neutrino Beamline”. arXiv:1412.3086 [physics.ins-det].
  15. ^ nuPRISM Collaboration (7 July 2016). “Proposal for the NuPRISM Experiment in the J-PARC Neutrino Beamline” (PDF)Archived (PDF) from the original on 2 December 2020. Retrieved 1 April 2020.
  16. ^ Mark Hartz (2020-07-29). “Near Detectors for the Hyper-K Neutrino Experiment”40th International Conference on High Energy Physics (ICHEP 2020).
  17. Jump up to:a b Umut Kose (on behalf of the Hyper-Kamiokande Collaboration) (2023-12-07). “The Hyper-Kamiokande Experiment: Status and Prospect”The 17th International Workshop on Tau Lepton Physics (TAU2023). Retrieved 2024-02-08.
  18. Jump up to:a b c “Hyper-Kamiokande website: Hyper-Kamiokande Detector”.
  19. Jump up to:a b Jan Kisiel (Silesia U.) for the Hyper-Kamiokande collaboration (Jun 28, 2023). “Photodetection and electronic system for the Hyper-Kamiokande Water Cherenkov detectors”Nucl. Instrum. Meth. A1055: 168482. Bibcode:2023NIMPA105568482Kdoi:10.1016/j.nima.2023.168482.
  20. ^ Hyper-Kamiokande Proto-Collaboration (June 20, 2019). “Physics potentials with the second Hyper-Kamiokande detector in Korea”Progress of Theoretical and Experimental Physics2018 (6): 063C01. arXiv:1611.06118doi:10.1093/ptep/pty044.
  21. ^ Shiozawa, M. (23–25 September 1999). “Study of 1-Megaton water Cherenkov detectors for the future proton decay search”. AIP Conf.Proc. 533 (2000) 1, 21–24. International Workshop on Next Generation Nucleon Decay and Neutrino Detector (NNN99). Stony Brook, NY, United States. doi:10.1063/1.1361719.
  22. ^ Nakamura, K. (2000). “HYPER-KAMIOKANDE: A next generation water Cherenkov detector for a nucleon decay experiment”Part of Neutrino Oscillations and Their Origin. Proceedings, 1st Workshop, Fujiyoshida, Japan, February 11–13: 359–363.
  23. ^ K. Abe; et al. (15 September 2011). “Letter of Intent: The Hyper-Kamiokande Experiment — Detector Design and Physics Potential —“. arXiv:1109.3262 [hep-ex].
  24. ^ “Hyper-Kamiokande website: The Inaugural Symposium of the Hyper-K Proto-Collaboration”. Kashiwa, Japan. February 5, 2015.
  25. ^ “Proto-collaboration formed to promote Hyper-Kamiokande”. CERN Courier. 9 April 2015.
  26. ^ “Hyper-Kamiokande construction to start in 2020”. CERN Courier. 28 September 2018.
  27. ^ “Groundbreaking ceremony for Hyper-Kamiokande held in Hida, Japan”. The University of Tokyo. 28 May 2021.
  28. ^ Itow, on behalf of the Hyper-Kamiokande Collaboration, Y. (2021). “Construction status and prospects of the Hyper-Kamiokande project”. Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021). Proceedings of Science. p. 1192. doi:10.22323/1.395.1192S2CID 199687331.
  29. ^ “Hyper-Kamiokande experiment; Excavation of the gigantic underground cavern has finally begun”.
  30. ^ “Kamioka Observatory website: Completion of the main cavern dome section of the Hyper-Kamiokande experiment”. 11 October 2023.

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