Papers
Topics
Authors
Recent
Search
2000 character limit reached

Leptonic neutral-current probes in a short-distance DUNE-like setup

Published 31 Jan 2024 in hep-ph and hep-ex | (2402.00114v3)

Abstract: Precision measurements of neutrino-electron scattering may provide a viable way to test the non-minimal form of the charged and neutral current weak interactions within a hypothetical near-detector setup for the Deep Underground Neutrino Experiment (DUNE). Although low-statistics, these processes are clean and provide information complementing the results derived from oscillation studies. They could shed light on the scale of neutrino mass generation in low-scale seesaw schemes.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (79)
  1. T.Ā Kajita, ā€œNobel Lecture: Discovery of atmospheric neutrino oscillations,ā€ Rev.Mod.Phys. 88 (2016) 030501.
  2. A.Ā B. McDonald, ā€œNobel Lecture: The Sudbury Neutrino Observatory: Observation of flavor change for solar neutrinos,ā€ Rev.Mod.Phys. 88 (2016) 030502.
  3. COHERENT Collaboration, D.Ā Akimov etĀ al., ā€œObservation of Coherent Elastic Neutrino-Nucleus Scattering,ā€ Science 357 no.Ā 6356, (2017) 1123ā€“1126, arXiv:1708.01294 [nucl-ex].
  4. COHERENT Collaboration, D.Ā Akimov etĀ al., ā€œCOHERENT Collaboration data release from the first observation of coherent elastic neutrino-nucleus scattering,ā€ arXiv:1804.09459 [nucl-ex].
  5. D.Ā Z. Freedman, ā€œCoherent Neutrino Nucleus Scattering as a Probe of the Weak Neutral Current,ā€ Phys. Rev. D 9 (1974) 1389ā€“1392.
  6. A.Ā Drukier and L.Ā Stodolsky, ā€œPrinciples and Applications of a Neutral Current Detector for Neutrino Physics and Astronomy,ā€ Phys. Rev. D 30 (1984) 2295.
  7. J.Ā Schechter and J.Ā W.Ā F. Valle, ā€œNeutrino Masses in SU(2) x U(1) Theories,ā€ Phys.Rev.D 22 (1980) 2227.
  8. J.Ā Schechter and J.Ā W.Ā F. Valle, ā€œNeutrino Decay and Spontaneous Violation of Lepton Number,ā€ Phys.Rev.D 25 (1982) 774.
  9. J.Ā W.Ā F. Valle, ā€œResonant Oscillations of Massless Neutrinos in Matter,ā€ Phys.Lett. B199 (1987) 432ā€“436.
  10. H.Ā Nunokawa etĀ al., ā€œResonant conversion of massless neutrinos in supernovae,ā€ Phys.Rev. D54 (1996) 4356ā€“4363.
  11. D.Ā Grasso, H.Ā Nunokawa, and J.Ā W.Ā F. Valle, ā€œPulsar velocities without neutrino mass,ā€ Phys.Rev.Lett. 81 (1998) 2412ā€“2415.
  12. R.Ā Mohapatra and J.Ā W.Ā F. Valle, ā€œNeutrino Mass and Baryon Number Nonconservation in Superstring Models,ā€ vol.Ā 34, p.Ā 1642. 1986.
  13. M.Ā Gonzalez-Garcia and J.Ā W.Ā F. Valle, ā€œFast Decaying Neutrinos and Observable Flavor Violation in a New Class of Majoron Models,ā€ Phys.Lett. B216 (1989) 360ā€“366.
  14. E.Ā K. Akhmedov etĀ al., ā€œLeft-right symmetry breaking in NJL approach,ā€ Phys.Lett.B 368 (1996) 270ā€“280, arXiv:hep-ph/9507275 [hep-ph].
  15. E.Ā K. Akhmedov etĀ al., ā€œDynamical left-right symmetry breaking,ā€ Phys.Rev.D 53 (1996) 2752ā€“2780, arXiv:hep-ph/9509255 [hep-ph].
  16. M.Ā Malinsky, J.Ā Romao, and J.Ā W.Ā F. Valle, ā€œNovel supersymmetric SO(10) seesaw mechanism,ā€ Phys.Rev.Lett. 95 (2005) 161801, arXiv:hep-ph/0506296 [hep-ph].
  17. F.Ā Escrihuela etĀ al., ā€œOn the description of nonunitary neutrino mixing,ā€ Phys.Rev. D92 (2015) 053009, arXiv:1503.08879 [hep-ph].
  18. F.Ā Escrihuela, D.Ā Forero, O.Ā Miranda, M.Ā TĆ³rtola, and J.Ā W.Ā F. Valle, ā€œProbing CP violation with non-unitary mixing in long-baseline neutrino oscillation experiments: DUNE as a case study,ā€ New J.Phys. 19 (2017) 093005, arXiv:1612.07377 [hep-ph].
  19. C.Ā S. Fong, H.Ā Minakata, and H.Ā Nunokawa, ā€œA framework for testing leptonic unitarity by neutrino oscillation experiments,ā€ JHEP 02 (2017) 114, arXiv:1609.08623 [hep-ph].
  20. S.-F. Ge, P.Ā Pasquini, M.Ā Tortola, and J.Ā W.Ā F. Valle, ā€œMeasuring the leptonic CP phase in neutrino oscillations with nonunitary mixing,ā€ Phys.Rev. D95 (2017) 033005, arXiv:1605.01670 [hep-ph].
  21. O.Ā Miranda and J.Ā W.Ā F. Valle, ā€œNeutrino oscillations and the seesaw origin of neutrino mass,ā€ Nucl.Phys. B908 (2016) 436ā€“455, arXiv:1602.00864 [hep-ph].
  22. O.Ā Miranda, M.Ā Tortola, and J.Ā W.Ā F. Valle, ā€œNew ambiguity in probing CP violation in neutrino oscillations,ā€ Phys.Rev.Lett. 117 (2016) 061804, arXiv:1604.05690 [hep-ph].
  23. C.Ā S. Fong, H.Ā Minakata, and H.Ā Nunokawa, ā€œNon-unitary evolution of neutrinos in matter and the leptonic unitarity test,ā€ JHEP 02 (2019) 015, arXiv:1712.02798 [hep-ph].
  24. L.Ā S. Miranda, P.Ā Pasquini, U.Ā Rahaman, and S.Ā Razzaque, ā€œSearching for non-unitary neutrino oscillations in the present T2K and NOĪ½šœˆ\nuitalic_Ī½A data,ā€ Eur. Phys. J. C 81 no.Ā 5, (2021) 444, arXiv:1911.09398 [hep-ph].
  25. O.Ā G. Miranda, D.Ā K. Papoulias, O.Ā Sanders, M.Ā TĆ³rtola, and J.Ā W.Ā F. Valle, ā€œFuture CEvNS experiments as probes of lepton unitarity and light-sterile neutrinos,ā€ Phys. Rev. D 102 (2020) 113014, arXiv:2008.02759 [hep-ph].
  26. I.Ā Martinez-Soler and H.Ā Minakata, ā€œMeasuring tau neutrino appearance probability via unitarity,ā€ Phys. Rev. D 104 no.Ā 9, (2021) 093006, arXiv:2109.06933 [hep-ph].
  27. U.Ā Rahaman and S.Ā Razzaque, ā€œNon-Unitary Neutrino Mixing in the NOĪ½šœˆ\nuitalic_Ī½A Near Detector Data,ā€ Universe 8 no.Ā 4, (2022) 238, arXiv:2108.11783 [hep-ph].
  28. C.Ā Soumya, ā€œProbing nonunitary neutrino mixing via long-baseline neutrino oscillation experiments based at J-PARC,ā€ Phys. Rev. D 105 no.Ā 1, (2022) 015012, arXiv:2104.04315 [hep-ph].
  29. D.Ā Kaur, N.Ā R.Ā K. Chowdhury, and U.Ā Rahaman, ā€œEffect of non-unitary mixing on the mass hierarchy and CP violation determination at the Protvino to Orca experiment,ā€ arXiv:2110.02917 [hep-ph].
  30. Y.Ā Wang and S.Ā Zhou, ā€œNon-unitary leptonic flavor mixing and CP violation in neutrino-antineutrino oscillations,ā€ Phys. Lett. B 824 (2022) 136797, arXiv:2109.13622 [hep-ph].
  31. S.Ā S. Chatterjee, O.Ā G. Miranda, M.Ā TĆ³rtola, and J.Ā W.Ā F. Valle, ā€œNonunitarity of the lepton mixing matrix at the European Spallation Source,ā€ Phys. Rev. D 106 no.Ā 7, (2022) 075016, arXiv:2111.08673 [hep-ph].
  32. S.Ā Gariazzo, P.Ā MartĆ­nez-MiravĆ©, O.Ā Mena, S.Ā Pastor, and M.Ā TĆ³rtola, ā€œNon-unitary three-neutrino mixing in the early Universe,ā€ JCAP 03 (2023) 046, arXiv:2211.10522 [hep-ph].
  33. D.Ā Aloni and A.Ā Dery, ā€œRevisiting leptonic non-unitarity in light of FASERĪ½šœˆ\nuitalic_Ī½,ā€ arXiv:2211.09638 [hep-ph].
  34. S.Ā Sahoo, S.Ā Das, A.Ā Kumar, and S.Ā K. Agarwalla, ā€œConstraining non-unitary neutrino mixing using matter effects in atmospheric neutrinos at INO-ICAL,ā€ arXiv:2309.16942 [hep-ph].
  35. J.Ā M. Celestino-RamĆ­rez, F.Ā J. Escrihuela, L.Ā J. Flores, and O.Ā G. Miranda, ā€œTesting the non-unitarity of the leptonic mixing matrix at FASER,ā€ arXiv:2309.00116 [hep-ph].
  36. O.Ā G. Miranda, D.Ā K. Papoulias, O.Ā Sanders, M.Ā TĆ³rtola, and J.Ā W.Ā F. Valle, ā€œLow-energy probes of sterile neutrino transition magnetic moments,ā€ JHEP 12 (2021) 191, arXiv:2109.09545 [hep-ph].
  37. T.Ā Schwetz and A.Ā Segarra, ā€œT violation in nonstandard neutrino oscillation scenarios,ā€ Phys. Rev. D 105 no.Ā 5, (2022) 055001, arXiv:2112.08801 [hep-ph].
  38. T.Ā Schwetz and A.Ā Segarra, ā€œModel-Independent Test of T Violation in Neutrino Oscillations,ā€ Phys. Rev. Lett. 128 no.Ā 9, (2022) 091801, arXiv:2106.16099 [hep-ph].
  39. J.Ā Tang, S.Ā Vihonen, and Y.Ā Xu, ā€œPrecision measurements and tau neutrino physics in a future accelerator neutrino experiment,ā€ Commun. Theor. Phys. 74 no.Ā 3, (2022) 035201, arXiv:2108.11107 [hep-ph].
  40. J.Ā Arrington etĀ al., ā€œPhysics Opportunities for the Fermilab Booster Replacement,ā€ arXiv:2203.03925 [hep-ph].
  41. F.Ā Capozzi, C.Ā Giunti, and C.Ā A. Ternes, ā€œImproved sensitivities of ESSĪ½šœˆ\nuitalic_Ī½SB from a two-detector fit,ā€ JHEP 04 (2023) 130, arXiv:2302.07154 [hep-ph].
  42. S.Ā R. Soleti, P.Ā Coloma, J.Ā J.Ā G. Cadenas, and A.Ā Cabrera, ā€œSearch for Hidden Neutrinos at the European Spallation Source: the SHiNESS experiment,ā€ arXiv:2311.18509 [hep-ex].
  43. O.Ā Miranda etĀ al., ā€œExploring the Potential of Short-Baseline Physics at Fermilab,ā€ Phys.Rev. D97 (2018) 095026, arXiv:1802.02133 [hep-ph].
  44. P.Ā Coloma, J.Ā LĆ³pez-PavĆ³n, S.Ā Rosauro-Alcaraz, and S.Ā Urrea, ā€œNew physics from oscillations at the DUNE near detector, and the role of systematic uncertainties,ā€ JHEP 08 (2021) 065, arXiv:2105.11466 [hep-ph].
  45. P.Ā deĀ Salas etĀ al., ā€œ2020 global reassessment of the neutrino oscillation picture,ā€ JHEP 02 (2021) 071, arXiv:2006.11237 [hep-ph].
  46. M.Ā Blennow, P.Ā Coloma, E.Ā Fernandez-Martinez, J.Ā Hernandez-Garcia, and J.Ā Lopez-Pavon, ā€œNon-Unitarity, sterile neutrinos, and Non-Standard neutrino Interactions,ā€ JHEP 04 (2017) 153, arXiv:1609.08637 [hep-ph].
  47. Particle Data Group Collaboration, R.Ā L. Workman and Others, ā€œReview of Particle Physics,ā€ PTEP 2022 (2022) 083C01.
  48. D.Ā Forero, C.Ā Giunti, C.Ā Ternes, and M.Ā Tortola, ā€œNon-unitary neutrino mixing in short and long-baseline experiments,ā€ arXiv:2103.01998 [hep-ph].
  49. Z.Ā Hu, J.Ā Ling, J.Ā Tang, and T.Ā Wang, ā€œGlobal oscillation data analysis on the 3ā¢Ī½3šœˆ3\nu3 italic_Ī½ mixing without unitarity,ā€ JHEP 01 (2021) 124, arXiv:2008.09730 [hep-ph].
  50. S.Ā A.Ā R. Ellis, K.Ā J. Kelly, and S.Ā W. Li, ā€œCurrent and Future Neutrino Oscillation Constraints on Leptonic Unitarity,ā€ JHEP 12 (2020) 068, arXiv:2008.01088 [hep-ph].
  51. S.Ā K. Agarwalla, S.Ā Das, A.Ā Giarnetti, and D.Ā Meloni, ā€œModel-independent constraints on non-unitary neutrino mixing from high-precision long-baseline experiments,ā€ JHEP 07 (2022) 121, arXiv:2111.00329 [hep-ph].
  52. D.Ā Bryman, V.Ā Cirigliano, A.Ā Crivellin, and G.Ā Inguglia, ā€œTesting Lepton Flavor Universality with Pion, Kaon, Tau, and Beta Decays,ā€ Ann.Rev.Nucl.Part.Sci. 72 (2022) 69ā€“91, arXiv:2111.05338 [hep-ph].
  53. F.Ā J. Escrihuela, L.Ā J. Flores, and O.Ā G. Miranda, ā€œNeutrino counting experiments and non-unitarity from LEP and future experiments,ā€ Phys. Lett. B 802 (2020) 135241, arXiv:1907.12675 [hep-ph].
  54. D.Ā Forero, S.Ā Morisi, M.Ā Tortola, and J.Ā W.Ā F. Valle, ā€œLepton flavor violation and non-unitary lepton mixing in low-scale type-I seesaw,ā€ JHEP 09 (2011) 142, arXiv:1107.6009 [hep-ph].
  55. M.Ā Lindner, M.Ā Platscher, and F.Ā S. Queiroz, ā€œA Call for New Physics : The Muon Anomalous Magnetic Moment and Lepton Flavor Violation,ā€ Phys. Rept. 731 (2018) 1ā€“82, arXiv:1610.06587 [hep-ph].
  56. M.Ā Blennow, E.Ā FernĆ”ndez-MartĆ­nez, J.Ā HernĆ”ndez-GarcĆ­a, J.Ā LĆ³pez-PavĆ³n, X.Ā Marcano, and D.Ā Naredo-Tuero, ā€œBounds on lepton non-unitarity and heavy neutrino mixing,ā€ JHEP 08 (2023) 030, arXiv:2306.01040 [hep-ph].
  57. J.Ā Bernabeu etĀ al., ā€œLepton Flavor Nonconservation at High-Energies in a Superstring Inspired Standard Model,ā€ Phys.Lett.B 187 (1987) 303ā€“308.
  58. M.Ā Gonzalez-Garcia and J.Ā W.Ā F. Valle, ā€œFast Decaying Neutrinos and Observable Flavor Violation in a New Class of Majoron Models,ā€ Phys.Lett.B 216 (1989) 360ā€“366.
  59. A.Ā Abada, M.Ā E. Krauss, W.Ā Porod, F.Ā Staub, A.Ā Vicente, and C.Ā Weiland, ā€œLepton flavor violation in low-scale seesaw models: SUSY and non-SUSY contributions,ā€ JHEP 11 (2014) 048, arXiv:1408.0138 [hep-ph].
  60. C.Ā Hagedorn, J.Ā Kriewald, J.Ā Orloff, and A.Ā M. Teixeira, ā€œFlavour and CP symmetries in the inverse seesaw,ā€ Eur. Phys. J. C 82 no.Ā 3, (2022) 194, arXiv:2107.07537 [hep-ph].
  61. M.Ā Dittmar, A.Ā Santamaria, M.Ā Gonzalez-Garcia, and J.Ā W.Ā F. Valle, ā€œProduction Mechanisms and Signatures of Isosinglet Neutral Heavy Leptons in Z0superscriptš‘0Z^{0}italic_Z start_POSTSUPERSCRIPT 0 end_POSTSUPERSCRIPT Decays,ā€ Nucl.Phys.B 332 (1990) 1ā€“19.
  62. M.Ā Gonzalez-Garcia, A.Ā Santamaria, and J.Ā W.Ā F. Valle, ā€œIsosinglet Neutral Heavy Lepton Production in Zš‘Zitalic_Z Decays and Neutrino Mass,ā€ Nucl.Phys.B 342 (1990) 108ā€“126.
  63. A.Ā Atre, T.Ā Han, S.Ā Pascoli, and B.Ā Zhang, ā€œThe Search for Heavy Majorana Neutrinos,ā€ JHEP 05 (2009) 030, arXiv:0901.3589 [hep-ph].
  64. J.Ā Aguilar-Saavedra etĀ al., ā€œFlavour in heavy neutrino searches at the LHC,ā€ Phys.Rev.D 85 (2012) 091301, arXiv:1203.5998 [hep-ph].
  65. S.Ā Das, F.Ā Deppisch, O.Ā Kittel, and J.Ā W.Ā F. Valle, ā€œHeavy Neutrinos and Lepton Flavour Violation in Left-Right Symmetric Models at the LHC,ā€ Phys.Rev.D 86 (2012) 055006, arXiv:1206.0256 [hep-ph].
  66. F.Ā F. Deppisch, N.Ā Desai, and J.Ā W.Ā F. Valle, ā€œIs charged lepton flavor violation a high energy phenomenon?,ā€ Phys.Rev.D 89 (2014) 051302, arXiv:1308.6789 [hep-ph].
  67. S.Ā Antusch and O.Ā Fischer, ā€œTesting sterile neutrino extensions of the Standard Model at future lepton colliders,ā€ JHEP 05 (2015) 053, arXiv:1502.05915 [hep-ph].
  68. F.Ā F. Deppisch, P.Ā S. BhupalĀ Dev, and A.Ā Pilaftsis, ā€œNeutrinos and Collider Physics,ā€ New J. Phys. 17 no.Ā 7, (2015) 075019, arXiv:1502.06541 [hep-ph].
  69. M.Ā Hirsch and Z.Ā S. Wang, ā€œHeavy neutral leptons at ANUBIS,ā€ Phys. Rev. D 101 no.Ā 5, (2020) 055034, arXiv:2001.04750 [hep-ph].
  70. G.Ā Cottin etĀ al., ā€œLong-lived heavy neutral leptons with a displaced shower signature at CMS,ā€ JHEP 02 (2023) 011, arXiv:2210.17446 [hep-ph].
  71. G.Ā Chauhan, P.Ā S.Ā B. Dev, I.Ā Dubovyk, B.Ā Dziewit, W.Ā Flieger, K.Ā Grzanka, J.Ā Gluza, B.Ā Karmakar, and S.Ā Zieba, ā€œPhenomenology of Lepton Masses and Mixing with Discrete Flavor Symmetries, ,ā€ arXiv:2310.20681 [hep-ph].
  72. A.Ā Batra, P.Ā Bharadwaj, S.Ā Mandal, R.Ā Srivastava, and J.Ā W.Ā F. Valle, ā€œPhenomenology of the simplest linear seesaw mechanism,ā€ JHEP 07 (2023) 221, arXiv:2305.00994 [hep-ph].
  73. S.Ā Alekhin etĀ al., ā€œA facility to Search for Hidden Particles at the CERN SPS: the SHiP physics case,ā€ Rept. Prog. Phys. 79 no.Ā 12, (2016) 124201, arXiv:1504.04855 [hep-ph].
  74. CMS Collaboration, ā€œSearch for heavy Majorana neutrinos in the same-sign dilepton channel in proton-proton collisions at sš‘ \sqrt{s}square-root start_ARG italic_s end_ARG = 13 TeV,ā€.
  75. ATLAS Collaboration, M.Ā Aaboud etĀ al., ā€œSearch for heavy Majorana or Dirac neutrinos and right-handed Wš‘ŠWitalic_W gauge bosons in final states with two charged leptons and two jets at s=13š‘ 13\sqrt{s}=13square-root start_ARG italic_s end_ARG = 13 TeV with the ATLAS detector,ā€ JHEP 01 (2019) 016, arXiv:1809.11105 [hep-ex].
  76. J.Ā Alimena etĀ al., ā€œSearching for long-lived particles beyond the Standard Model at the Large Hadron Collider,ā€ J. Phys. G 47 no.Ā 9, (2020) 090501, arXiv:1903.04497 [hep-ex].
  77. CMS Collaboration, A.Ā Tumasyan etĀ al., ā€œSearch for long-lived heavy neutral leptons with displaced vertices in proton-proton collisions at ss\sqrt{\mathrm{s}}square-root start_ARG roman_s end_ARG =13 TeV,ā€ JHEP 07 (2022) 081, arXiv:2201.05578 [hep-ex].
  78. A.Ā M. Abdullahi etĀ al., ā€œThe present and future status of heavy neutral leptons,ā€ J. Phys. G 50 no.Ā 2, (2023) 020501, arXiv:2203.08039 [hep-ph].
  79. CMS Collaboration, ā€œSearch for long-lived heavy neutral leptons with lepton flavour conserving or violating decays to a jet and a charged lepton,ā€ arXiv:2312.07484 [hep-ex].
Citations (1)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up

Tweets

Sign up for free to view the 2 tweets with 3 likes about this paper.

Sign Up for Free