The ENUBET monitored neutrino beam and its implementation at CERN

ENUBET collaboration: L. Hali\'c; F. Acerbi; I. Angelis; L. Bomben; M.; Bonesini; F. Bramati; A. Branca; C. Brizzolari; G. Brunetti; M. Calviani; S.; Capelli; M. Capitani; S. Carturan; M.G. Catanesi; S. Cecchini; N.; Charitonidis; F. Cindolo; G. Cogo; G. Collazuol; F. Dal Corso; C. Delogu; G.; De Rosa; A. Falcone; B.Goddard; A. Gola; D. Guffanti; F. Iacob; M.A.; Jebramcik; C. Jollet; V. Kain; A. Kallitsopoulou; B. Kli\v{c}ek; Y. Kudenko,; Ch. Lampoudis; M. Laveder; P. Legou; A. Longhin; L. Ludovici; E. Lutsenko; L.; Magaletti; G. Mandrioli; S. Marangoni; A. Margotti; V. Mascagna; N. Mauri; J.; McElwee; L. Meazza; A. Meregaglia; M. Mezzetto; M. Nessi; A. Paoloni; M.; Pari; T. Papaevangelou; E.G. Parozzi; L. Pasqualini; G. Paternoster; L.; Patrizii; M. Pozzato; M. Prest; F. Pupilli; E. Radicioni; A.C. Ruggeri; G.; Saibene; D. Sampsonidis; A. Scanu; C. Scian; G. Sirri; R. Speziali; M.; Stip\v{c}evi\'c; M. Tenti; F. Terranova; M. Torti; S.E. Tzamarias; E.; Vallazza; F. Velotti; L. Votano

arXiv:2501.04531·hep-ex·January 9, 2025

The ENUBET monitored neutrino beam and its implementation at CERN

ENUBET collaboration: L. Hali\'c, F. Acerbi, I. Angelis, L. Bomben, M., Bonesini, F. Bramati, A. Branca, C. Brizzolari, G. Brunetti, M. Calviani, S., Capelli, M. Capitani, S. Carturan, M.G. Catanesi, S. Cecchini, N., Charitonidis, F. Cindolo, G. Cogo, G. Collazuol, F. Dal Corso

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TL;DR

The ENUBET project developed a monitored neutrino beam with high precision flux measurement capabilities, tested its instrumentation, and is now planning a site-specific implementation at CERN to enable unprecedented neutrino cross section measurements.

Contribution

This work introduces a site-dependent design of a monitored neutrino beam at CERN, including a new beamline and instrumentation, for high-precision neutrino cross section measurements.

Findings

01

A horn-less static focusing beamline enables 1% $ u_e$ cross section measurement.

02

A cost-effective calorimeter successfully identifies leptons in the decay tunnel.

03

Flux systematics are constrained to 1% using charged lepton observables.

Abstract

The ENUBET project recently concluded the R&D for a site independent design of a monitored neutrino beam for high precision cross section measurements, in which the neutrino flux is inferred from the measurement of charged leptons in an instrumented decay tunnel. In this phase three fundamental results were obtained and will be discussed here: 1) a beamline not requiring a horn and relying on static focusing elements allows to perform a $ν_{e}$ cross section measurement in the DUNE energy range with 1% statistical uncertainty employing $1 0^{20}$ 400 GeV protons on target (pot) and a neutrino detector of the size of ProtoDUNE; 2) the instrumentation of the decay tunnel, based on a cost effective sampling calorimeter solution, has been tested with a large scale prototype achieving the performance required to identify positrons and muons from kaon decays with high signal-to-noise ratio; 3)…

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Taxonomy

TopicsNeutrino Physics Research · Particle Detector Development and Performance · Particle physics theoretical and experimental studies