Papers
Topics
Authors
Recent
Search
2000 character limit reached

Probing for chiral $Z^\prime$ gauge boson through scattering measurement experiments

Published 19 Jul 2023 in hep-ph, astro-ph.HE, and hep-ex | (2307.09737v2)

Abstract: Motivated by the observation of tiny neutrino mass can not be explained within the framework of Standard Model (SM), we consider extra gauge extended scenarios in which tiny neutrino masses are generated through seesaw mechanism. These scenarios are equipped with beyond the standard model (BSM) neutral gauge boson called $Z\prime$ in the general $U(1)X$ symmetry which is a linear combination of $U(1)_Y$ and $U(1){B-L}$. In this case, left and right handed fermions interact differently with the $Z\prime$. The $Z\prime$ gives rise to different processes involving neutrino-nucleon, neutrino-electron, electron-nucleus and electron-muon scattering processes. By comparing with proton, electron beam-dump experiments data, recast data from searches for the long-lived and dark photon at BaBaR, LHCb and CMS experiments, the electron and muon $g-2$ data, and the data of the dilepton and dijet searches at the LEP experiment, we derive bounds on the gauge coupling and the corresponding gauge boson mass for different $U(1)_X$ charges and evaluate the prospective limits from the future beam-dump scenarios at DUNE, FASER(2) and ILC. We conclude that large parameter regions could be probed by scattering, beam-dump and collider experiments in future.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (123)
  1. Particle Data Group Collaboration, “Review of Particle Physics,” PTEP 2020 (2020) 083C01.
  2. G. Bertone, D. Hooper, and J. Silk, “Particle dark matter: Evidence, candidates and constraints,” Phys.  Rept. 405 (2005) 279–390 [hep-ph/0404175].
  3. Planck Collaboration, “Planck 2018 results. VI. Cosmological parameters,” Astron. Astrophys.  641 (2020) A6 [arXiv:1807.06209]. [Erratum: Astron.Astrophys. 652, C4 (2021)].
  4. P. Minkowski, “μ→e⁢γ→𝜇𝑒𝛾\mu\to e\gammaitalic_μ → italic_e italic_γ at a Rate of One Out of 109superscript10910^{9}10 start_POSTSUPERSCRIPT 9 end_POSTSUPERSCRIPT Muon Decays?” Phys. Lett.  B 67 (1977) 421–428.
  5. O. Sawada and A. Sugamoto, eds., “Horizontal gauge symmetry and masses of neutrinos,” Conf.  Proc.  C 7902131 (1979) 95–99.
  6. M. Gell-Mann, P. Ramond, and R. Slansky, “Complex Spinors and Unified Theories,” Conf.  Proc.  C 790927 (1979) 315–321 [arXiv:1306.4669].
  7. R. N. Mohapatra and G. Senjanovic, “Neutrino Mass and Spontaneous Parity Nonconservation,” Phys.  Rev.  Lett. 44 (1980) 912.
  8. J. Schechter and J. W. F. Valle, “Neutrino Masses in SU(2) x U(1) Theories,” Phys.  Rev. D 22 (1980) 2227.
  9. S. Weinberg, “Baryon and Lepton Nonconserving Processes,” Phys.  Rev.  Lett. 43 (1979) 1566–1570.
  10. K. Asai, A. Das, J. Li, T. Nomura, and O. Seto, “Chiral Z’ in FASER, FASER2, DUNE, and ILC beam dump experiments,” Phys.  Rev.  D 106 (2022) 095033 [arXiv:2206.12676].
  11. M. Bauer, P. Foldenauer, and J. Jaeckel, “Hunting All the Hidden Photons,” JHEP 07 (2018) 094 [arXiv:1803.05466].
  12. P. Ilten, Y. Soreq, M. Williams, and W. Xue, “Serendipity in dark photon searches,” JHEP 06 (2018) 004 [arXiv:1801.04847].
  13. P. S. B. Dev, B. Dutta, K. J. Kelly, R. N. Mohapatra, and Y. Zhang, “Light, long-lived B −-- L gauge and Higgs bosons at the DUNE near detector,” JHEP 07 (2021) 166 [arXiv:2104.07681].
  14. C. Baruch, P. Ilten, Y. Soreq, and M. Williams, “Axial vectors in DarkCast,” JHEP 11 (2022) 124 [arXiv:2206.08563].
  15. A. Greljo, P. Stangl, A. E. Thomsen, and J. Zupan, “On (g −-- 2)μ𝜇{}_{\mu}start_FLOATSUBSCRIPT italic_μ end_FLOATSUBSCRIPT from gauged U(1)X𝑋{}_{X}start_FLOATSUBSCRIPT italic_X end_FLOATSUBSCRIPT,” JHEP 07 (2022) 098 [arXiv:2203.13731].
  16. N. Bernal and Y. Farzan, “Neutrino nonstandard interactions with arbitrary couplings to u and d quarks,” Phys.  Rev.  D 107 (2023) 035007 [arXiv:2211.15686].
  17. A. Boyarsky, O. Mikulenko, M. Ovchynnikov, and L. Shchutska, “Searches for new physics at SND@LHC,” JHEP 03 (2022) 006 [arXiv:2104.09688].
  18. S. Ansarifard and Y. Farzan, “Neutral exotica at FASERν𝜈\nuitalic_ν and SND@LHC,” JHEP 02 (2022) 049 [arXiv:2109.13962].
  19. A. Aboubrahim, M. M. Altakach, M. Klasen, P. Nath, and Z.-Y. Wang, “Combined constraints on dark photons and discovery prospects at the LHC and the Forward Physics Facility,” JHEP 03 (2023) 182 [arXiv:2212.01268].
  20. F. Kling, J.-L. Kuo, S. Trojanowski, and Y.-D. Tsai, “FLArE up dark sectors with EM form factors at the LHC forward physics facility,” Nucl.  Phys.  B 987 (2023) 116103 [arXiv:2205.09137].
  21. K. J. Kelly, P. A. N. Machado, A. Marchionni, and Y. F. Perez-Gonzalez, “LEvEL: Low-Energy Neutrino Experiment at the LHC,” JHEP 08 (2021) 087 [arXiv:2103.00009].
  22. P. S. B. Dev, D. Kim, K. Sinha, and Y. Zhang, “New interference effects from light gauge bosons in neutrino-electron scattering,” Phys.  Rev.  D 104 (2021) 075001 [arXiv:2105.09309].
  23. G. Chauhan, P. S. B. Dev, and X.-J. Xu, “Probing the ν𝜈\nuitalic_νR-philic Z’ at DUNE near detectors,” Phys.  Lett.  B 841 (2023) 137907 [arXiv:2204.11876].
  24. R. Coy and X.-J. Xu, “Probing the muon g −-- 2 with future beam dump experiments,” JHEP 10 (2021) 189 [arXiv:2108.05147].
  25. A. L. Foguel, G. M. Salla, and R. Z. Funchal, “(In)Visible signatures of the minimal dark abelian gauge sector,” JHEP 12 (2022) 063 [arXiv:2209.03383].
  26. M. Lindner, F. S. Queiroz, W. Rodejohann, and X.-J. Xu, “Neutrino-electron scattering: general constraints on Z′superscript𝑍′Z^{\prime}italic_Z start_POSTSUPERSCRIPT ′ end_POSTSUPERSCRIPT and dark photon models,” JHEP 05 (2018) 098 [arXiv:1803.00060].
  27. K. Chakraborty, A. Das, S. Goswami, and S. Roy, “Constraining general U(1) interactions from neutrino-electron scattering measurements at DUNE near detector,” JHEP 04 (2022) 008 [arXiv:2111.08767].
  28. A. Ismail, R. Mammen Abraham, and F. Kling, “Neutral current neutrino interactions at FASERν𝜈\nuitalic_ν,” Phys.  Rev.  D 103 (2021) 056014 [arXiv:2012.10500].
  29. P. Bakhti, Y. Farzan, and S. Pascoli, “Discovery potential of FASERν𝜈\nuitalic_ν with contained vertex and through-going events,” JHEP 04 (2021) 075 [arXiv:2010.16312].
  30. K. Cheung and C. J. Ouseph, “Sensitivities on dark photon from the forward physics experiments,” JHEP 10 (2022) 196 [arXiv:2208.04523].
  31. K. Cheung, C. J. Ouseph, and T. Wang, “Non-standard neutrino and Z’ interactions at the FASERν𝜈\nuitalic_ν and the LHC,” JHEP 12 (2021) 209 [arXiv:2111.08375].
  32. P. Bakhti, Y. Farzan, and S. Pascoli, “Unravelling the richness of dark sector by FASERν𝜈\nuitalic_ν,” JHEP 10 (2020) 008 [arXiv:2006.05437].
  33. P. S. B. Dev, W. Rodejohann, X.-J. Xu, and Y. Zhang, “MUonE sensitivity to new physics explanations of the muon anomalous magnetic moment,” JHEP 05 (2020) 053 [arXiv:2002.04822].
  34. A. Masiero, P. Paradisi, and M. Passera, “New physics at the MUonE experiment at CERN,” Phys. Rev.  D 102 (2020) 075013 [arXiv:2002.05418].
  35. N. Nath, N. Okada, S. Okada, D. Raut, and Q. Shafi, “Light Z′superscript𝑍′Z^{\prime}italic_Z start_POSTSUPERSCRIPT ′ end_POSTSUPERSCRIPT and Dirac fermion dark matter in the B−L𝐵𝐿B-Litalic_B - italic_L model,” Eur.  Phys.  J. C 82 (2022) 864 [arXiv:2112.08960].
  36. L. M. G. de la Vega, L. J. Flores, N. Nath, and E. Peinado, “Complementarity between dark matter direct searches and CEν𝜈\nuitalic_νNS experiments in U(1)’ models,” JHEP 09 (2021) 146 [arXiv:2107.04037].
  37. T. Araki, K. Asai, H. Otono, T. Shimomura, and Y. Takubo, “Dark photon from light scalar boson decays at FASER,” JHEP 03 (2021) 072 [arXiv:2008.12765]. [Erratum: JHEP 06, 087 (2021)].
  38. T. Felkl, T. Li, J. Liao, and M. A. Schmidt, “Probing general U⁢(1)′𝑈superscript1′U(1)^{\prime}italic_U ( 1 ) start_POSTSUPERSCRIPT ′ end_POSTSUPERSCRIPT models with non-universal lepton charges at FASER/FASER2, COHERENT and long-baseline oscillation experiments.” arXiv:2306.09569.
  39. A. Elpe, E. Akyumuk, T. M. Aliev, L. Selbuz, and I. Turan, “Constraining nonminimal dark sector scenarios with the COHERENT neutrino scattering data,” Phys.  Rev. D 107 (2023) 075022 [arXiv:2212.06861].
  40. P. Melas, D. K. Papoulias, and N. Saoulidou, “Probing generalized neutrino interactions with DUNE Near Detector.” arXiv:2303.07094.
  41. FASER Collaboration, “Technical Proposal for FASER: ForwArd Search ExpeRiment at the LHC.” arXiv:1812.09139.
  42. FASER Collaboration, “FASER: ForwArd Search ExpeRiment at the LHC.” arXiv:1901.04468.
  43. FASER Collaboration, “First neutrino interaction candidates at the LHC,” Phys. Rev.  D 104 (2021) L091101 [arXiv:2105.06197].
  44. FASER Collaboration, “Detecting and Studying High-Energy Collider Neutrinos with FASER at the LHC,” Eur.  Phys.  J. C 80 (2020) 61 [arXiv:1908.02310].
  45. FASER Collaboration, “Technical Proposal: FASERnu.” arXiv:2001.03073.
  46. FASER Collaboration, “Measuring TeV neutrinos with FASERν𝜈\nuitalic_ν in LHC Run 3,” PoS EPS-HEP2021 (2022) 248.
  47. C. e. a. Ahdida, “SND@LHC - Scattering and Neutrino Detector at the LHC,” CERN, Geneva, 2021.
  48. SHiP Collaboration, “A facility to Search for Hidden Particles (SHiP) at the CERN SPS.” arXiv:1504.04956.
  49. SND@LHC Collaboration, “SND@LHC: The Scattering and Neutrino Detector at the LHC.” arXiv:2210.02784.
  50. SHiP Collaboration, “SND@LHC.” arXiv:2002.08722.
  51. NA64 Collaboration, “Search for a New B-L Z’ Gauge Boson with the NA64 Experiment at CERN,” Phys.  Rev. Lett.  129 (2022) 161801 [arXiv:2207.09979].
  52. NA64 Collaboration, “Search for invisible decays of sub-GeV dark photons in missing-energy events at the CERN SPS,” Phys.  Rev. Lett.  118 (2017) 011802 [arXiv:1610.02988].
  53. NA64 Collaboration, “Search for vector mediator of Dark Matter production in invisible decay mode,” Phys.  Rev.  D 97 (2018) 072002 [arXiv:1710.00971].
  54. S. N. Gninenko, N. V. Krasnikov, and V. A. Matveev, “Search for dark sector physics with NA64,” Phys.  Part.  Nucl. 51 (2020) 829–858 [arXiv:2003.07257].
  55. G. Abbiendi, “Letter of Intent: the MUonE project,CERN-SPSC-2019-026, SPSC-I-252,” CERN, Geneva, 2019.
  56. G. Abbiendi, “Status of the MUonE experiment,” Phys.  Scripta 97 (2022) 054007 [arXiv:2201.13177].
  57. M. Davier and H. Nguyen Ngoc, “An Unambiguous Search for a Light Higgs Boson,” Phys. Lett.  B 229 (1989) 150–155.
  58. NA64 Collaboration, “Improved limits on a hypothetical X(16.7) boson and a dark photon decaying into e+⁢e−superscript𝑒superscript𝑒e^{+}e^{-}italic_e start_POSTSUPERSCRIPT + end_POSTSUPERSCRIPT italic_e start_POSTSUPERSCRIPT - end_POSTSUPERSCRIPT pairs,” Phys.  Rev.  D 101 (2020) 071101 [arXiv:1912.11389].
  59. TEXONO Collaboration, “Measurement of Nu(e)-bar -Electron Scattering Cross-Section with a CsI(Tl) Scintillating Crystal Array at the Kuo-Sheng Nuclear Power Reactor,” Phys.  Rev.  D 81 (2010) 072001 [arXiv:0911.1597].
  60. TEXONO Collaboration, “Limit on the electron neutrino magnetic moment from the Kuo-Sheng reactor neutrino experiment,” Phys.  Rev.  Lett. 90 (2003) 131802 [hep-ex/0212003].
  61. TEXONO Collaboration, “A Search of Neutrino Magnetic Moments with a High-Purity Germanium Detector at the Kuo-Sheng Nuclear Power Station,” Phys.  Rev.  D 75 (2007) 012001 [hep-ex/0605006].
  62. Borexino Collaboration, “Science and technology of BOREXINO: A Real time detector for low-energy solar neutrinos,” Astropart.  Phys. 16 (2002) 205–234 [hep-ex/0012030].
  63. F. von Feilitzsch and N. Schmitz, eds., “The Homestake chlorine solar neutrino experiment: Past, present and future,” Nucl.  Phys.  B Proc.  Suppl.  118 (2003) 49–54.
  64. Borexino Collaboration, “First real time detection of Be-7 solar neutrinos by Borexino,” Phys.  Lett.  B 658 (2008) 101–108 [arXiv:0708.2251].
  65. Borexino Collaboration, “The Borexino detector at the Laboratori Nazionali del Gran Sasso,” Nucl.  Instrum. Meth.  A 600 (2009) 568–593 [arXiv:0806.2400].
  66. CHARM-II Collaboration, “An Improved determination of the electroweak mixing angle from muon-neutrino electron scattering,” Phys.  Lett.  B 259 (1991) 499–507.
  67. CHARM-II Collaboration, “A Detector for the Study of Neutrino - Electron Scattering,” Nucl.  Instrum. Meth.  A 278 (1989) 670.
  68. CHARM-II Collaboration, “Measurement of differential cross-sections for muon-neutrino electron scattering,” Phys.  Lett.  B 302 (1993) 351–355.
  69. CHARM-II Collaboration, “Precision measurement of electroweak parameters from the scattering of muon-neutrinos on electrons,” Phys.  Lett.  B 335 (1994) 246–252.
  70. COHERENT Collaboration, “COHERENT Collaboration data release from the first observation of coherent elastic neutrino-nucleus scattering.” arXiv:1804.09459.
  71. M. Cadeddu, C. Giunti, Y. F. Li, and Y. Y. Zhang, “Average CsI neutron density distribution from COHERENT data,” Phys.  Rev. Lett.  120 (2018) 072501 [arXiv:1710.02730].
  72. COHERENT Collaboration, “First Measurement of Coherent Elastic Neutrino-Nucleus Scattering on Argon,” Phys.  Rev. Lett.  126 (2021) 012002 [arXiv:2003.10630].
  73. COHERENT Collaboration, “COHERENT Collaboration data release from the first detection of coherent elastic neutrino-nucleus scattering on argon.” arXiv:2006.12659.
  74. CMS Collaboration, “Search for prompt production of a GeV scale resonance decaying to a pair of muons in proton-proton collisions at $\sqrts=13~\mathrmTeV.”.
  75. BaBar Collaboration, “Search for a Dark Photon in e+⁢e−superscript𝑒superscript𝑒e^{+}e^{-}italic_e start_POSTSUPERSCRIPT + end_POSTSUPERSCRIPT italic_e start_POSTSUPERSCRIPT - end_POSTSUPERSCRIPT Collisions at BaBar,” Phys.  Rev. Lett.  113 (2014) 201801 [arXiv:1406.2980].
  76. BaBar Collaboration, “Search for Invisible Decays of a Dark Photon Produced in e+⁢e−superscript𝑒superscript𝑒{e}^{+}{e}^{-}italic_e start_POSTSUPERSCRIPT + end_POSTSUPERSCRIPT italic_e start_POSTSUPERSCRIPT - end_POSTSUPERSCRIPT Collisions at BaBar,” Phys.  Rev. Lett.  119 (2017) 131804 [arXiv:1702.03327].
  77. NOMAD Collaboration, “Final NOMAD results on muon-neutrino —>>> tau-neutrino and electron-neutrino —>>> tau-neutrino oscillations including a new search for tau-neutrino appearance using hadronic tau decays,” Nucl.  Phys.  B 611 (2001) 3–39 [hep-ex/0106102].
  78. CHARM Collaboration, “Search for Axion Like Particle Production in 400-GeV Proton - Copper Interactions,” Phys.  Lett.  B 157 (1985) 458–462.
  79. J. Blumlein and J. Brunner, “New Exclusion Limits for Dark Gauge Forces from Beam-Dump Data,” Phys.  Lett.  B 701 (2011) 155–159 [arXiv:1104.2747].
  80. J. Blümlein and J. Brunner, “New Exclusion Limits on Dark Gauge Forces from Proton Bremsstrahlung in Beam-Dump Data,” Phys.  Lett.  B 731 (2014) 320–326 [arXiv:1311.3870].
  81. ALEPH, DELPHI, L3, OPAL, LEP Electroweak Working Group Collaboration, “A Combination of preliminary electroweak measurements and constraints on the standard model.” hep-ex/0612034.
  82. ALEPH Collaboration, “Study of the muon pair production at center-of-mass energies from 20-GeV to 136-GeV with the ALEPH detector,” Phys.  Lett.  B 399 (1997) 329–341.
  83. LEP Working Group for Higgs boson searches, ALEPH, DELPHI, L3, OPAL Collaboration, “Search for the standard model Higgs boson at LEP,” Phys.  Lett.  B 565 (2003) 61–75 [hep-ex/0306033].
  84. ALEPH, DELPHI, L3, OPAL, SLD, LEP Electroweak Working Group, SLD Electroweak Group, SLD Heavy Flavour Group Collaboration, “Precision electroweak measurements on the Z𝑍Zitalic_Z resonance,” Phys.  Rept. 427 (2006) 257–454 [hep-ex/0509008].
  85. A. Davidson, M. Koca, and K. C. Wali, “U(1) as the Minimal Horizontal Gauge Symmetry,” Phys. Rev.  Lett.  43 (1979) 92.
  86. R. N. Mohapatra and R. E. Marshak, “Local B-L Symmetry of Electroweak Interactions, Majorana Neutrinos and Neutron Oscillations,” Phys.  Rev.  Lett. 44 (1980) 1316–1319. [Erratum: Phys.Rev.Lett. 44, 1643 (1980)].
  87. C. Wetterich, “Neutrino Masses and the Scale of B-L Violation,” Nucl.  Phys.  B 187 (1981) 343–375.
  88. A. Masiero, J. F. Nieves, and T. Yanagida, “B−superscript𝐵B^{-}italic_B start_POSTSUPERSCRIPT - end_POSTSUPERSCRIPTl Violating Proton Decay and Late Cosmological Baryon Production,” Phys.  Lett.  B 116 (1982) 11–15.
  89. W. Buchmuller, C. Greub, and P. Minkowski, “Neutrino masses, neutral vector bosons and the scale of B-L breaking,” Phys.  Lett.  B 267 (1991) 395–399.
  90. S. Jung, H. Murayama, A. Pierce, and J. D. Wells, “Top quark forward-backward asymmetry from new t-channel physics,” Phys.  Rev.  D 81 (2010) 015004 [arXiv:0907.4112].
  91. T. Nomura and H. Okada, “Minimal realization of right-handed gauge symmetry,” Phys. Rev.  D 97 (2018) 015015 [arXiv:1707.00929].
  92. T. Nomura and H. Okada, “Loop suppressed light fermion masses with U⁢(1)R𝑈subscript1𝑅U(1)_{R}italic_U ( 1 ) start_POSTSUBSCRIPT italic_R end_POSTSUBSCRIPT gauge symmetry,” Phys.  Rev.  D 96 (2017) 015016 [arXiv:1704.03382].
  93. S. Jana, P. K. Vishnu, and S. Saad, “Minimal dirac neutrino mass models from U⁢(1)RUsubscript1R\hbox{U}(1)_{\mathrm{R}}U ( 1 ) start_POSTSUBSCRIPT roman_R end_POSTSUBSCRIPT gauge symmetry and left–right asymmetry at colliders,” Eur.  Phys.  J. C 79 (2019) 916 [arXiv:1904.07407].
  94. O. Seto and T. Shimomura, “Atomki anomaly in gauged U(1)R𝑅{}_{R}start_FLOATSUBSCRIPT italic_R end_FLOATSUBSCRIPT symmetric model,” JHEP 04 (2021) 025 [arXiv:2006.05497].
  95. J. C. Montero and V. Pleitez, “Gauging U(1) symmetries and the number of right-handed neutrinos,” Phys.  Lett. B675 (2009) 64–68 [arXiv:0706.0473].
  96. E. Ma, “Naturally small seesaw neutrino mass with no new physics beyond the TeV scale,” Phys. Rev.  Lett.  86 (2001) 2502–2504 [hep-ph/0011121].
  97. CMS Collaboration, “Search for resonant and nonresonant new phenomena in high-mass dilepton final states at s𝑠\sqrt{s}square-root start_ARG italic_s end_ARG = 13 TeV,” JHEP 07 (2021) 208 [arXiv:2103.02708].
  98. ATLAS Collaboration, “Search for high-mass dilepton resonances using 139 fb−11{}^{-1}start_FLOATSUPERSCRIPT - 1 end_FLOATSUPERSCRIPT of p⁢p𝑝𝑝ppitalic_p italic_p collision data collected at s=𝑠absent\sqrt{s}=square-root start_ARG italic_s end_ARG =13 TeV with the ATLAS detector,” Phys.  Lett.  B 796 (2019) 68–87 [arXiv:1903.06248].
  99. F. Wang, W. Wang, and J. M. Yang, “Split two-Higgs-doublet model and neutrino condensation,” Europhys.  Lett. 76 (2006) 388–394 [hep-ph/0601018].
  100. S. Gabriel and S. Nandi, “A New two Higgs doublet model,” Phys.  Lett. B655 (2007) 141–147 [hep-ph/0610253].
  101. S. M. Davidson and H. E. Logan, “Dirac neutrinos from a second Higgs doublet,” Phys. Rev.  D80 (2009) 095008 [arXiv:0906.3335].
  102. N. Haba and M. Hirotsu, “TeV-scale seesaw from a multi-Higgs model,” Eur.  Phys.  J. C69 (2010) 481–492 [arXiv:1005.1372].
  103. F. Kling and L. J. Nevay, “Forward neutrino fluxes at the LHC,” Phys.  Rev.  D 104 (2021) 113008 [arXiv:2105.08270].
  104. S. N. Gninenko, D. V. Kirpichnikov, M. M. Kirsanov, and N. V. Krasnikov, “The exact tree-level calculation of the dark photon production in high-energy electron scattering at the CERN SPS,” Phys.  Lett.  B 782 (2018) 406–411 [arXiv:1712.05706].
  105. G. Abbiendi, “Letter of Intent: the MUonE project,” CERN, Geneva, 2019. The collaboration has not yet a structure, therefore the names above are for the moment an indication of contacts.
  106. C. M. Carloni Calame, M. Passera, L. Trentadue, and G. Venanzoni, “A new approach to evaluate the leading hadronic corrections to the muon g𝑔gitalic_g-2,” Phys.  Lett.  B 746 (2015) 325–329 [arXiv:1504.02228].
  107. FASER Collaboration, “First Direct Observation of Collider Neutrinos with FASER at the LHC,” Phys.  Rev. Lett.  131 (2023) 031801 [arXiv:2303.14185].
  108. NA62 Collaboration, “Search for dark photon decays to μ−⁢μ−superscript𝜇superscript𝜇\mu^{-}\mu^{-}italic_μ start_POSTSUPERSCRIPT - end_POSTSUPERSCRIPT italic_μ start_POSTSUPERSCRIPT - end_POSTSUPERSCRIPT at NA62,” JHEP 09 (2023) 035 [arXiv:2303.08666].
  109. COHERENT Collaboration, “Measurement of the Coherent Elastic Neutrino-Nucleus Scattering Cross Section on CsI by COHERENT,” Phys.  Rev. Lett.  129 (2022) 081801 [arXiv:2110.07730].
  110. COHERENT Collaboration, “Observation of Coherent Elastic Neutrino-Nucleus Scattering,” Science 357 (2017) 1123–1126 [arXiv:1708.01294].
  111. J. Barranco, O. G. Miranda, and T. I. Rashba, “Probing new physics with coherent neutrino scattering off nuclei,” JHEP 12 (2005) 021 [hep-ph/0508299].
  112. K. Patton, J. Engel, G. C. McLaughlin, and N. Schunck, “Neutrino-nucleus coherent scattering as a probe of neutron density distributions,” Phys.  Rev.  C 86 (2012) 024612 [arXiv:1207.0693].
  113. J. Erler and S. Su, “The Weak Neutral Current,” Prog.  Part.  Nucl. Phys.  71 (2013) 119–149 [arXiv:1303.5522].
  114. R. H. Helm, “Inelastic and Elastic Scattering of 187-Mev Electrons from Selected Even-Even Nuclei,” Phys.  Rev.  104 (1956) 1466–1475.
  115. I. Angeli and K. P. Marinova, “Table of experimental nuclear ground state charge radii: An update,” Atom.  Data Nucl.  Data Tabl.  99 (2013) 69–95.
  116. M. Bender, K. Rutz, P. G. Reinhard, J. A. Maruhn, and W. Greiner, “Shell structure of superheavy nuclei in selfconsistent mean field models,” Phys.  Rev.  C 60 (1999) 034304 [nucl-th/9906030].
  117. ALEPH, DELPHI, L3, OPAL, LEP Electroweak Collaboration, “Electroweak Measurements in Electron-Positron Collisions at W-Boson-Pair Energies at LEP,” Phys.  Rept. 532 (2013) 119–244 [arXiv:1302.3415].
  118. LHCb Collaboration, “Search for A′→μ+⁢μ−→superscript𝐴′superscript𝜇superscript𝜇A^{\prime}\to\mu^{+}\mu^{-}italic_A start_POSTSUPERSCRIPT ′ end_POSTSUPERSCRIPT → italic_μ start_POSTSUPERSCRIPT + end_POSTSUPERSCRIPT italic_μ start_POSTSUPERSCRIPT - end_POSTSUPERSCRIPT Decays,” Phys.  Rev. Lett.  124 (2020) 041801 [arXiv:1910.06926].
  119. A. Belyaev, N. D. Christensen, and A. Pukhov, “CalcHEP 3.4 for collider physics within and beyond the Standard Model,” Comput.  Phys. Commun.  184 (2013) 1729–1769 [arXiv:1207.6082].
  120. F. Jegerlehner and A. Nyffeler, “The Muon g-2,” Phys.  Rept. 477 (2009) 1–110 [arXiv:0902.3360].
  121. R. H. Parker, C. Yu, W. Zhong, B. Estey, and H. Müller, “Measurement of the fine-structure constant as a test of the Standard Model,” Science 360 (2018) 191 [arXiv:1812.04130].
  122. L. Morel, Z. Yao, P. Cladé, and S. Guellati-Khélifa, “Determination of the fine-structure constant with an accuracy of 81 parts per trillion,” Nature 588 (2020) 61–65.
  123. Muon g-2 Collaboration, “Measurement of the Positive Muon Anomalous Magnetic Moment to 0.46 ppm,” Phys.  Rev. Lett.  126 (2021) 141801 [arXiv:2104.03281].
Citations (1)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Summarize

Paper to Video (Beta)

Whiteboard

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

Ai Sparkles Streamline Icon: https://streamlinehq.com Sign Up to Generate

Open Problems

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

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Continue Learning

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

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now

Collections

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

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up

Tweets

Sign up for free to view the 1 tweet with 0 likes about this paper.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up for Free