ENUBET

The Enhanced NeUtrino BEams from kaon Tagging or ENUBET[1] is an ERC funded project[2] that aims at producing an artificial neutrino beam in which the flavor, flux and energy of the produced neutrinos are known with unprecedented precision.

Interest in these types of high precision neutrino beams has grown significantly in the last ten years,[3] especially after the start of the construction of the DUNE and Hyper-Kamiokande detectors. DUNE and Hyper-Kamiokande are aimed at discovering CP violation in neutrinos observing a small difference between the probability of a muon-neutrino to oscillate into an electron-neutrino and the probability of a muon-antineutrino to oscillate into an electron-antineutrino. This effect points toward a difference in the behavior of matter and antimatter. In quantum field theory, this effect is described by a violation of the CP symmetry in particle physics.

The experiments that will measure CP violation need a very precise knowledge of the neutrino cross-sections, i.e. the probability for a neutrino to interact in the detector.[4] This probability is measured counting the number of interacting neutrinos divided by the flux of incoming neutrinos. Current neutrino cross-section experiments are limited by large uncertainties in the neutrino flux. A new generation of cross-section experiment is therefore needed to overcome these limitations with new techniques or high precision beams, as ENUBET.[5][6]

In ENUBET, neutrinos are produced by focusing mesons in a narrow band beam towards an instrumented decay tunnel, where charged leptons produced in association with neutrinos by mesons' decay can be monitored at the single particle level. Beams like ENUBET are called monitored neutrino beams.

Mesons (essentially pions and kaons) are produced in the interactions of accelerated protons with a Beryllium or Graphite target. The proposed facility is being studied taking into account the energies of currently available proton drivers: 400 GeV (CERN SPS), 120 GeV (FNAL Main Injector), 30 GeV (J-PARC Main Ring).

Kaons and pions are momentum and charge selected in a short transfer line by means of dipole and quadrupole magnets and are focused in a collimated beam into an instrumented decay tube. Large angle muons and positrons from kaon decays (, , ) are measured by detectors on the tunnel walls, while muons from pion decays () are monitored after the hadron dump at the end of the tunnel. The decay region is kept short (40 m) in order to reduce the neutrino contamination from muon decays ().

In this way the neutrino flux is assessed in a direct way with a precision of 1%, without relying on complex simulations of the transfer line and on hadro-production data extrapolation that currently limit the knowledge of the flux to 5-10%.[7] The ENUBET facility can be used to perform precision studies of the neutrino cross section and of sterile neutrinos or Non-Standard Interaction models. This method can also be extended to detect other leptons in order to have a complete monitored neutrino beam.[8]

The ENUBET project started in 2016. It involves 13 European institutions in 5 European countries, and brings together 60 scientists.

ENUBET studies all technical and physics challenges to demonstrate the feasibility of a monitored neutrino beam: it will build a full-scale demonstrator of the instrumented decay tunnel (3 m length and partial azimuthal coverage) and will assess costs and physics reach of the proposed facility.

Since March 2019, ENUBET is part of the CERN Neutrino Platform[9] (NP06/ENUBET) for the development of a new generation of neutrino detector and facilities.

References

  1. "ENUBET - Enhanced NeUtrino BEams from kaon Tagging". enubet.pd.infn.it. Retrieved 2019-12-07.
  2. "ERC grant agreement ID: 681647".
  3. Katori, T. (2018). "Neutrino–nucleus cross sections for oscillation experiments". J. Phys. G. 45 (1): 013001. arXiv:1611.07770. Bibcode:2018JPhG...45a3001K. doi:10.1088/1361-6471/aa8bf7. S2CID 119468689.
  4. Ankowski, A. M.; Mariani, C. (2017). "Systematic uncertainties in long-baseline neutrino-oscillation experiments". J. Phys. G. 44 (5): 054001. arXiv:1609.00258. Bibcode:2017JPhG...44e4001A. doi:10.1088/1361-6471/aa61b2. S2CID 59414695.
  5. Mezzetto, M (2018). "Other future accelerator experiments". doi:10.5281/zenodo.1286826. {{cite journal}}: Cite journal requires |journal= (help)
  6. Dell'Acqua, Andrea; Aduszkiewicz, Antoni; Ahlers, Markus; Aihara, Hiroaki; Alion, Tyler; Saul Alonso Monsalve; Luis Alvarez Ruso; Antonelli, Vito; Babicz, Marta; Anastasia Maria Barbano; Pasquale di Bari; Baussan, Eric; Bellini, Vincenzo; Berardi, Vincenzo; Blondel, Alain; Bonesini, Maurizio; Booth, Alexander; Bordoni, Stefania; Boyarsky, Alexey; Boyd, Steven; Bross, Alan D.; Brunner, Juergen; Carlile, Colin; Catanesi, Maria-Gabriella; Christodoulou, Georgios; Coan, Thomas; Cussans, David; Patrick Decowski, M.; Albert De Roeck; et al. (2018). "Future Opportunities in Accelerator-based Neutrino Physics". arXiv:1812.06739 [hep-ex].
  7. Soplin, Leonidas Aliaga (2016-01-01). "Neutrino Flux Prediction for the NuMI Beamline". doi:10.2172/1254643. {{cite journal}}: Cite journal requires |journal= (help)
  8. Longhin, A.; Ludovici, L.; Terranova, F. (2015). "A novel technique for the measurement of the electron neutrino cross section". Eur. Phys. J. C. 75 (4): 155. arXiv:1412.5987. Bibcode:2015EPJC...75..155L. doi:10.1140/epjc/s10052-015-3378-9. S2CID 52245662.
  9. "CERN Neutrino Platform | CERN". home.cern. Retrieved 2019-12-07.
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