Your search keyword '"Water Cherenkov detector"' showing total 7 results

1. Neutrino-induced reactions on 18O and implications of 18O mixture in water Cherenkov detectors on supernova neutrino events.

Author

Suzuki, Toshio, Nakazato, Ken'ichiro, and Sakuda, Makoto

Subjects

*CHERENKOV counters, *NEUTRINO detectors, *THRESHOLD energy, *NEUTRINO oscillation, *NEUTRINOS, *ELECTRON scattering, *ELECTRONS

Abstract

Neutrino-nucleus reaction cross sections on 18O are evaluated by shell-model calculations and compared with those on 16O. Important contributions from Gamow-Teller transitions are noticed for 18O (ν e , e−) 18F in contrary to the case for 16O, where spin-dipole transitions are dominant contributions. Calculated cross sections for 18O (ν e , e−) 18F are shown to be larger than for 16O at low neutrino energies below 20 MeV in natural water with the 0.205% admixture of 18O due to the lower threshold energy (1.66 MeV) for 18O than that for 16O (15.42 MeV). The resulting electron spectra, that is, the cross sections as functions of emitted electron energy T e , are also shown to be quite different, reflecting the different threshold energies. The electron spectra from (ν e , e−) reactions on 18O and 16O in water Cherenkov detectors for supernova neutrino detection are investigated for both the cases with and without the neutrino oscillation and compared with those of the neutrino-electron scattering. It has been shown that the contribution from 18O (0.205% mixture) enhances the rates from 16O by 60% for the case without the oscillation and by 20-30% for the case with the oscillation below T e =20 MeV. For the case with the neutrino oscillation, the event rates for 18O and 16O become comparable to those of the neutrino-electron scattering. However, their rates at low energy (T e < 20 MeV) are much lower than those of the neutrino-electron scattering, which is important for the pointing accuracy to the supernova direction. [ABSTRACT FROM AUTHOR]

Published

2023

2. Photodetection and electronic system for the Hyper-Kamiokande Water Cherenkov detectors.

Author

Kisiel, Jan

Subjects

*ELECTRONIC systems, *CP violation, *CHERENKOV counters, *NEUTRINO oscillation, *GROUNDWATER, *PARTICLES (Nuclear physics)

Abstract

Hyper-Kamiokande is a next-generation neutrino experiment built in Japan and is scheduled to become operational in 2027. It will be the world's largest underground water Cherenkov detector instrumented with three kinds of photomultipliers (PMTs): 20- and 3- inch PMTs, supplemented with multi-PMTs. The physics program of the Hyper-Kamiokande experiment will address the most important, unsolved questions in physics, including CP violation in neutrino oscillations and nucleon decay. An overview of the experiment is presented, emphasizing photo-sensors and electronics. [ABSTRACT FROM AUTHOR]

Published

2023

3. Solar results from Super-Kamiokande.

Author

Yusuke Koshio

Subjects

*SOLAR neutrinos, *NEUTRINO oscillation, *NUCLEAR reactors, *FLUX (Energy), *CHERENKOV counters, *NEUTRINO detectors

Abstract

The recent results of solar neutrino measurement from the Super-Kamiokande (SK) are presented. SK has four phases (SK-I to IV) since starting the operation in 1996. Thanks to the background reduction, the lowering energy threshold (3.5MeV) has achieved in SK-IV. The 4504 days of data of all the phases were combined for the analysis. More than 70,000 solar neutrino signal were totally observed, and no long term flux time variation was seen. The night flux was 3-4% higher than day flux, and it was the first indication of the neutrino oscillation of the matter effect of the earth at 3 sigma level. No significant distortion of the energy spectrum was seen. The precise neutrino oscillation analysis using SK data and the global analysis of solar and KamLAND reactor data were carried out. The obtained global neutrino oscillation parameters were determined as Δm²21 = 7.50 × 10-5eV² and sin²θ12 = 0.308. [ABSTRACT FROM AUTHOR]

Published

2015

4. Development and tests of WLS plates for Outer Detector of Hyper-Kamiokande.

Author

Kudenko, Y., Khotjantsev, A., Mineev, O., and Yershov, N.

Subjects

*DETECTORS, *LIGHT sources, *PHOTOMETRY, *PHOTOMULTIPLIERS, *CHERENKOV counters, *CHERENKOV radiation, *UNITS of measurement, *NEUTRINO oscillation

Abstract

This paper describes measurements of photosensing units developed for the Outer Detector of Hyper-Kamiokande to increase the effective acceptance of Cherenkov radiation. The photosensing unit consists of a photomultiplier and a wavelength shifting plate optically coupled to it. Plates doped with different fluors and covered by different reflectors were tested using UV LED light sources in air and water. The effects of wavelength shifting fluors, side reflectors, water interface, and shaping of optical coupling are studied. Results of measurements of the light yield and its uniformity are presented. [ABSTRACT FROM AUTHOR]

Published

2023

5. New Results from T2K.

Author

Nakaya, T.

Subjects

*NEUTRINO mass, *NEUTRINO oscillation, *ACQUISITION of data, *PROTONS, *RADIATION exposure, *NUCLEAR research

Abstract

Abstract: We report new results from the T2K neutrino oscillation experiment with additional data collected after recovering from damage by the Great East Japan Earthquake of March 11, 2011. With the exposure of protons on target, we observe 10 electron neutrino events in a muon neutrino beam with background events estimated for , which constitutes the evidence of electron neutrino appearance and . The observation corresponds to 3.2σ excess ( ), and results in for and for normal (inverted) mass hierarchy. This discovery opens the window to explore CP violation in the neutrino sector. [Copyright &y& Elsevier]

Published

2013

6. The ESS Based Neutrino Super Beam for CP Violation Discovery

Author

Marcos Dracos

Subjects

Physics, Particle physics, Astrophysics::High Energy Astrophysical Phenomena, Solar neutrino, High Energy Physics::Phenomenology, Super Beam, Solar neutrino problem, Physics and Astronomy(all), law.invention, leptonic CP violation, Nuclear physics, Magnetic horn, neutrino, Neutrino detector, Water Cherenkov detector, law, ESSnuSB, Measurements of neutrino speed, CP violation, Physics::Accelerator Physics, ESS, High Energy Physics::Experiment, Neutrino, Neutrino oscillation

Abstract

After measuring the last neutrino mixing angle θ13 and finding it relatively large, the observation of CP violation in the leptonic sector is now reachable with the condition to have significantly more intense neutrino beams than the existing ones. For this θ13 value, it came out that going to the second oscillation maximum instead of the first one, provides more sensitivity to CP violation. The European Spallation Source facility in Lund, designed to accelerate protons to 2.0 GeV at a repetition rate of 14 Hz for neutron production, could also be used to produce a copious number of neutrinos. Doubling the frequency of its proton linac opens the possibility to operate the facility simultaneously for neutron and neutrino production. An accumulator ring would be needed to shorten the pulses from 2.86 ms for neutrons to few μs in order to reduce to acceptable levels the electric current sent to the magnetic horn focusing charged mesons to acceptable levels for the neutrino production. This accumulator could also be used by the neutron facility to increase its performance. Coupled with a megaton Water Cherenkov far detector placed at the optimal distance, this facility could efficiently exploite the second oscillation maximum to cover a large fraction of the CP violation parameter δCP at 5 σ confidence level.

Published

2015

7. Towards a new Liquid Argon Imaging Chamber for the MODULAr project

Author

Alessandro Menegolli, C. Vignoli, F. Pietropaolo, R. Dolfini, F. Varanini, G. Mannocchi, Arnaud Ferrari, Paola Sala, G. Fiorillo, C. Rubbia, A. G. Cocco, Sandro Ventura, G. Meng, F. Cavanna, Angela Fava, C. Montanari, M. Cambiaghi, M. Rossella, S. Centro, A. Gigli Berzolari, A. Rappoldi, P. Benetti, A. Borio, Diego Angeli, G. Satta, L. Periale, K. Cieslik, G. Battistoni, B. Baibussinov, G.L. Raselli, Silvia Muraro, E. Calligarich, D. Gibin, M. Baldo Ceolin, Christian Farnese, P. Picchi, O. Palamara, A. Guglielmi, D., Angeli, B., Baibussinov, M. B., Ceolin, G., Battistoni, P., Benetti, A., Borio, E., Calligarich, M., Cambiaghi, F., Cavanna, S., Centro, K., Cieslik, A. G., Cocco, R., Dolfini, A. G., Berzolari, C., Farnese, A., Fava, A., Ferrari, Fiorillo, Giuliana, D., Gibin, A., Guglielmi, G., Mannocchi, A., Menegolli, G., Meng, C., Montanari, S., Muraro, O., Palamara, L., Periale, P., Picchi, F., Pietropaolo, A., Rappoldi, G. L., Raselli, M., Rossella, C., Rubbia, P., Sala, G., Satta, F., Varanini, S., Ventura, and C., Vignoli

Subjects

Liquid detectors, TRANSMISSION, Time projection chambers, Nuclear engineering, ICARUS, Nuclear physics, DESIGN, Particle tracking detectors, Detectors and Experimental Techniques, Neutrino oscillation, Instrumentation, WATER CHERENKOV DETECTOR, Mathematical Physics, Physics, Time projection chamber, Large detector systems for particle and astroparticle physics, business.industry, Detector, Volume (computing), GRAN-SASSO, Modular design, PERFORMANCE, Massless particle, LIGHT, IONIZING TRACKS, TPC, Neutrino, business, SCINTILLATION, Lepton

Abstract

The MODULAr project foresees the exploitation of a new liquid Argon imaging detector, of at least 20 kt fiducial mass, to be operated in a shallow depth location under the Gran Sasso Mountain. It will be devoted to study neutrino oscillations with an optimized off-axis CNGS neutrino beam. Cosmic neutrinos as well as proton decay will also be addressed. The MODULAr detector will vastly inherit from the technology developed for ICARUS-T600. However, such an increase in the volume over the current ICARUS-T600 needs to be carefully considered. It is concluded that a single, huge volume is an inoperable and uneconomical solution for many reasons. A very large mass is best realized with a modular set of many identical, independent units, each of about 5 kt, "cloning" the basic technology of the ICARUS-T600. Several of such modular units will be assembled to reach at least 20 kt as initial sensitive volume. The increase of the active volume of about one order of magnitude with respect to the ICARUS-T600 detector requires some specific R&D activity, which will be implemented in a similar to 360 ton prototype unit (SLICE) of reduced length.

Published

2009