Decay tunnel instrumentation for the ENUBET neutrino beam

F. Acerbi; A. Berra; M. Bonesini; A. Branca; C. Brizzolari; G. Brunetti; M. Calviani; S. Carturan; S. Capelli; M. G. Catanesi; N. Charitonidis; S. Cecchini; F. Cindolo; G. Collazuol; E. Conti; F. Dal Corso; G. De Rosa; C. Delogu; A. Falcone; A. Gola; C. Jollet; V. Kain; B. Klićek; Y. Kudenko; M. Laveder; A. Longhin; L. Ludovici; E. Lutsenko; L. Magaletti; G. Mandrioli; A. Margotti; V. Mascagna; N. Mauri; L. Meazza; A. Meregaglia; M. Mezzetto; M. Nessi; M. Pari; A. Paoloni; E. Parozzi; L. Pasqualini; G. Paternoster; L. Patrizii; M. Pozzato; M. Prest; F. Pupilli; E. Radicioni; C. Riccio; A. C. Ruggeri; C. Scian; G. Sirri; M. Stipćevic; M. Tenti; F. Terranova; M. Torti; E. Vallazza; F. Velotti; M. Vesco; L. Votano

doi:10.1088/1748-0221/15/05/C05059

Decay tunnel instrumentation for the ENUBET neutrino beam

F. Acerbi
, A. Berra
, M. Bonesini
, A. Branca
, C. Brizzolari
, G. Brunetti
, M. Calviani
, S. Carturan
, S. Capelli
, M. G. Catanesi
, N. Charitonidis
, S. Cecchini
, F. Cindolo
, G. Collazuol
, E. Conti
, F. Dal Corso
, G. De Rosa
, C. Delogu
, A. Falcone
, A. Gola

C. Jollet, V. Kain, B. Klićek, Y. Kudenko, M. Laveder, A. Longhin, L. Ludovici, E. Lutsenko, L. Magaletti, G. Mandrioli, A. Margotti, V. Mascagna, N. Mauri, L. Meazza, A. Meregaglia, M. Mezzetto, M. Nessi, M. Pari, A. Paoloni, E. Parozzi, L. Pasqualini, G. Paternoster, L. Patrizii, M. Pozzato, M. Prest, F. Pupilli, E. Radicioni, C. Riccio, A. C. Ruggeri, C. Scian, G. Sirri, M. Stipćevic, M. Tenti, F. Terranova, M. Torti, E. Vallazza, F. Velotti, M. Vesco, L. Votano

Physics and Astronomy

Fondazione Bruno Kessler
University of Trento
National Institute for Nuclear Physics
University of Insubria
University of Padua
University of Milan - Bicocca
CERN
Laboratori Nazionali di Legnaro
University of Naples Federico II
Université de Bordeaux
Ruder Boskovic Institute
Institute for Nuclear Research of the Russian Academy of Sciences
University of Bari
University of Bologna

Research output: Contribution to journal › Article › peer-review

Abstract

The uncertainty in the initial neutrino flux is the main limitation for a precise determination of the absolute neutrino cross section. The ERC funded ENUBET project (2016-2021) is studying a facility based on a narrow band beam to produce an intense source of electron neutrinos with a ten-fold improvement in accuracy. Since March 2019 ENUBET is also a Neutrino Platform experiment at CERN: NP06/ENUBET. A key element of the project is the instrumentation of the decay tunnel to monitor large angle positrons produced together with ν_e in the three body decays of kaons (K_e3) and to discriminate them from neutral and charged pions. The need for an efficient and high purity e/π separation over a length of several meters, and the requirements for fast response and radiation hardness imposed by the harsh beam environment, suggested the implementation of a longitudinally segmented Fe/scintillator calorimeter with a readout based on WLS fibers and SiPM detectors. An extensive experimental program through several test beam campaigns at the CERN-PS T9 beam line has been pursued on calorimeter prototypes, both with a shashlik and a lateral readout configuration. The latter, in which fibers collect the light from the side of the scintillator tiles, allows to place the light sensors away from the core of the calorimeter, thus reducing possible irradiation damages with respect to the shashlik design. This contribution will present the achievements of the prototyping activities carried out, together with irradiation tests made on the Silicon Photo-Multipliers. The results achieved so far pin down the technology of choice for the construction of the 3 m long demonstrator that will take data in 2021.

Original language	English
Article number	C05059
Journal	Journal of Instrumentation
Volume	15
Issue number	5
DOIs	https://doi.org/10.1088/1748-0221/15/05/C05059
State	Published - May 2020

Keywords

beam-intensity monitors
Beam-line instrumentation (beam position and profile monitors
bunch length monitors)
Calorimeters
Neutrino detectors
Particle identification methods

Access to Document

10.1088/1748-0221/15/05/C05059

Cite this

Acerbi, F., Berra, A., Bonesini, M., Branca, A., Brizzolari, C., Brunetti, G., Calviani, M., Carturan, S., Capelli, S., Catanesi, M. G., Charitonidis, N., Cecchini, S., Cindolo, F., Collazuol, G., Conti, E., Corso, F. D., Rosa, G. D., Delogu, C., Falcone, A., ... Votano, L. (2020). Decay tunnel instrumentation for the ENUBET neutrino beam. Journal of Instrumentation, 15(5), Article C05059. https://doi.org/10.1088/1748-0221/15/05/C05059

@article{f71b5951d442464eafb57503da2bdce4,

title = "Decay tunnel instrumentation for the ENUBET neutrino beam",

abstract = "The uncertainty in the initial neutrino flux is the main limitation for a precise determination of the absolute neutrino cross section. The ERC funded ENUBET project (2016-2021) is studying a facility based on a narrow band beam to produce an intense source of electron neutrinos with a ten-fold improvement in accuracy. Since March 2019 ENUBET is also a Neutrino Platform experiment at CERN: NP06/ENUBET. A key element of the project is the instrumentation of the decay tunnel to monitor large angle positrons produced together with νe in the three body decays of kaons (Ke3) and to discriminate them from neutral and charged pions. The need for an efficient and high purity e/π separation over a length of several meters, and the requirements for fast response and radiation hardness imposed by the harsh beam environment, suggested the implementation of a longitudinally segmented Fe/scintillator calorimeter with a readout based on WLS fibers and SiPM detectors. An extensive experimental program through several test beam campaigns at the CERN-PS T9 beam line has been pursued on calorimeter prototypes, both with a shashlik and a lateral readout configuration. The latter, in which fibers collect the light from the side of the scintillator tiles, allows to place the light sensors away from the core of the calorimeter, thus reducing possible irradiation damages with respect to the shashlik design. This contribution will present the achievements of the prototyping activities carried out, together with irradiation tests made on the Silicon Photo-Multipliers. The results achieved so far pin down the technology of choice for the construction of the 3 m long demonstrator that will take data in 2021.",

keywords = "beam-intensity monitors, Beam-line instrumentation (beam position and profile monitors, bunch length monitors), Calorimeters, Neutrino detectors, Particle identification methods",

author = "F. Acerbi and A. Berra and M. Bonesini and A. Branca and C. Brizzolari and G. Brunetti and M. Calviani and S. Carturan and S. Capelli and Catanesi, \{M. G.\} and N. Charitonidis and S. Cecchini and F. Cindolo and G. Collazuol and E. Conti and Corso, \{F. Dal\} and Rosa, \{G. De\} and C. Delogu and A. Falcone and A. Gola and C. Jollet and V. Kain and B. Kli{\'c}ek and Y. Kudenko and M. Laveder and A. Longhin and L. Ludovici and E. Lutsenko and L. Magaletti and G. Mandrioli and A. Margotti and V. Mascagna and N. Mauri and L. Meazza and A. Meregaglia and M. Mezzetto and M. Nessi and M. Pari and A. Paoloni and E. Parozzi and L. Pasqualini and G. Paternoster and L. Patrizii and M. Pozzato and M. Prest and F. Pupilli and E. Radicioni and C. Riccio and Ruggeri, \{A. C.\} and C. Scian and G. Sirri and M. Stip{\'c}evic and M. Tenti and F. Terranova and M. Torti and E. Vallazza and F. Velotti and M. Vesco and L. Votano",

note = "Publisher Copyright: {\textcopyright} 2020 IOP Publishing Ltd and Sissa Medialab.",

year = "2020",

month = may,

doi = "10.1088/1748-0221/15/05/C05059",

language = "English",

volume = "15",

journal = "Journal of Instrumentation",

issn = "1748-0221",

number = "5",

}

Acerbi, F, Berra, A, Bonesini, M, Branca, A, Brizzolari, C, Brunetti, G, Calviani, M, Carturan, S, Capelli, S, Catanesi, MG, Charitonidis, N, Cecchini, S, Cindolo, F, Collazuol, G, Conti, E, Corso, FD, Rosa, GD, Delogu, C, Falcone, A, Gola, A, Jollet, C, Kain, V, Klićek, B, Kudenko, Y, Laveder, M, Longhin, A, Ludovici, L, Lutsenko, E, Magaletti, L, Mandrioli, G, Margotti, A, Mascagna, V, Mauri, N, Meazza, L, Meregaglia, A, Mezzetto, M, Nessi, M, Pari, M, Paoloni, A, Parozzi, E, Pasqualini, L, Paternoster, G, Patrizii, L, Pozzato, M, Prest, M, Pupilli, F, Radicioni, E, Riccio, C, Ruggeri, AC, Scian, C, Sirri, G, Stipćevic, M, Tenti, M, Terranova, F, Torti, M, Vallazza, E, Velotti, F, Vesco, M & Votano, L 2020, 'Decay tunnel instrumentation for the ENUBET neutrino beam', Journal of Instrumentation, vol. 15, no. 5, C05059. https://doi.org/10.1088/1748-0221/15/05/C05059

TY - JOUR

T1 - Decay tunnel instrumentation for the ENUBET neutrino beam

AU - Acerbi, F.

AU - Berra, A.

AU - Bonesini, M.

AU - Branca, A.

AU - Brizzolari, C.

AU - Brunetti, G.

AU - Calviani, M.

AU - Carturan, S.

AU - Capelli, S.

AU - Catanesi, M. G.

AU - Charitonidis, N.

AU - Cecchini, S.

AU - Cindolo, F.

AU - Collazuol, G.

AU - Conti, E.

AU - Corso, F. Dal

AU - Rosa, G. De

AU - Delogu, C.

AU - Falcone, A.

AU - Gola, A.

AU - Jollet, C.

AU - Kain, V.

AU - Klićek, B.

AU - Kudenko, Y.

AU - Laveder, M.

AU - Longhin, A.

AU - Ludovici, L.

AU - Lutsenko, E.

AU - Magaletti, L.

AU - Mandrioli, G.

AU - Margotti, A.

AU - Mascagna, V.

AU - Mauri, N.

AU - Meazza, L.

AU - Meregaglia, A.

AU - Mezzetto, M.

AU - Nessi, M.

AU - Pari, M.

AU - Paoloni, A.

AU - Parozzi, E.

AU - Pasqualini, L.

AU - Paternoster, G.

AU - Patrizii, L.

AU - Pozzato, M.

AU - Prest, M.

AU - Pupilli, F.

AU - Radicioni, E.

AU - Riccio, C.

AU - Ruggeri, A. C.

AU - Scian, C.

AU - Sirri, G.

AU - Stipćevic, M.

AU - Tenti, M.

AU - Terranova, F.

AU - Torti, M.

AU - Vallazza, E.

AU - Velotti, F.

AU - Vesco, M.

AU - Votano, L.

PY - 2020/5

Y1 - 2020/5

N2 - The uncertainty in the initial neutrino flux is the main limitation for a precise determination of the absolute neutrino cross section. The ERC funded ENUBET project (2016-2021) is studying a facility based on a narrow band beam to produce an intense source of electron neutrinos with a ten-fold improvement in accuracy. Since March 2019 ENUBET is also a Neutrino Platform experiment at CERN: NP06/ENUBET. A key element of the project is the instrumentation of the decay tunnel to monitor large angle positrons produced together with νe in the three body decays of kaons (Ke3) and to discriminate them from neutral and charged pions. The need for an efficient and high purity e/π separation over a length of several meters, and the requirements for fast response and radiation hardness imposed by the harsh beam environment, suggested the implementation of a longitudinally segmented Fe/scintillator calorimeter with a readout based on WLS fibers and SiPM detectors. An extensive experimental program through several test beam campaigns at the CERN-PS T9 beam line has been pursued on calorimeter prototypes, both with a shashlik and a lateral readout configuration. The latter, in which fibers collect the light from the side of the scintillator tiles, allows to place the light sensors away from the core of the calorimeter, thus reducing possible irradiation damages with respect to the shashlik design. This contribution will present the achievements of the prototyping activities carried out, together with irradiation tests made on the Silicon Photo-Multipliers. The results achieved so far pin down the technology of choice for the construction of the 3 m long demonstrator that will take data in 2021.

AB - The uncertainty in the initial neutrino flux is the main limitation for a precise determination of the absolute neutrino cross section. The ERC funded ENUBET project (2016-2021) is studying a facility based on a narrow band beam to produce an intense source of electron neutrinos with a ten-fold improvement in accuracy. Since March 2019 ENUBET is also a Neutrino Platform experiment at CERN: NP06/ENUBET. A key element of the project is the instrumentation of the decay tunnel to monitor large angle positrons produced together with νe in the three body decays of kaons (Ke3) and to discriminate them from neutral and charged pions. The need for an efficient and high purity e/π separation over a length of several meters, and the requirements for fast response and radiation hardness imposed by the harsh beam environment, suggested the implementation of a longitudinally segmented Fe/scintillator calorimeter with a readout based on WLS fibers and SiPM detectors. An extensive experimental program through several test beam campaigns at the CERN-PS T9 beam line has been pursued on calorimeter prototypes, both with a shashlik and a lateral readout configuration. The latter, in which fibers collect the light from the side of the scintillator tiles, allows to place the light sensors away from the core of the calorimeter, thus reducing possible irradiation damages with respect to the shashlik design. This contribution will present the achievements of the prototyping activities carried out, together with irradiation tests made on the Silicon Photo-Multipliers. The results achieved so far pin down the technology of choice for the construction of the 3 m long demonstrator that will take data in 2021.

KW - beam-intensity monitors

KW - Beam-line instrumentation (beam position and profile monitors

KW - bunch length monitors)

KW - Calorimeters

KW - Neutrino detectors

KW - Particle identification methods

UR - https://www.scopus.com/pages/publications/85085997442

U2 - 10.1088/1748-0221/15/05/C05059

DO - 10.1088/1748-0221/15/05/C05059

M3 - Article

AN - SCOPUS:85085997442

SN - 1748-0221

VL - 15

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 5

M1 - C05059

ER -

Decay tunnel instrumentation for the ENUBET neutrino beam

Abstract

Keywords

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