Physics Potential of an Experiment using LHC Neutrinos

Production of neutrinos is abundant at LHC. Flavour composition and energy reach of the neutrino flux from proton-proton collisions depend on the pseudorapidity $\eta$. At large $\eta$, energies can exceed the TeV, with a sizeable contribution of the $\tau$ flavour. A dedicated detector could in...

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Autores principales: Beni, N., Brucoli, M., Buontempo, S., Cafaro, V., Dallavalle, G.M., Danzeca, S., De Lellis, G., Di Crescenzo, A., Giordano, V., Guandalini, C., Lazic, D., Lo Meo, S., Navarria, F.L., Szillasi, Z.
Lenguaje:eng
Publicado: 2019
Materias:
Detectors and Experimental Techniques
physics.ins-det
hep-ex
Particle Physics - Experiment
Acceso en línea:https://dx.doi.org/10.1088/1361-6471/ab3f7c
http://cds.cern.ch/record/2665801
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author Beni, N.
Brucoli, M.
Buontempo, S.
Cafaro, V.
Dallavalle, G.M.
Danzeca, S.
De Lellis, G.
Di Crescenzo, A.
Giordano, V.
Guandalini, C.
Lazic, D.
Lo Meo, S.
Navarria, F.L.
Szillasi, Z.
author_facet Beni, N.
Brucoli, M.
Buontempo, S.
Cafaro, V.
Dallavalle, G.M.
Danzeca, S.
De Lellis, G.
Di Crescenzo, A.
Giordano, V.
Guandalini, C.
Lazic, D.
Lo Meo, S.
Navarria, F.L.
Szillasi, Z.
author_sort Beni, N.
collection CERN
description Production of neutrinos is abundant at LHC. Flavour composition and energy reach of the neutrino flux from proton-proton collisions depend on the pseudorapidity $\eta$. At large $\eta$, energies can exceed the TeV, with a sizeable contribution of the $\tau$ flavour. A dedicated detector could intercept this intense neutrino flux in the forward direction, and measure the interaction cross section on nucleons in the unexplored energy range from a few hundred GeV to a few TeV. The high energies of neutrinos result in a larger $\nu$N interaction cross section, and the detector size can be relatively small. Machine backgrounds vary rapidly while moving along and away from the beam line. Four locations were considered as hosts for a neutrino detector: the CMS quadruplet region (~25 m from CMS Interaction Point (IP)), UJ53 and UJ57 (90 and 120 m from CMS IP), RR53 and RR57 (240 m from CMS IP), TI18 (480 m from ATLAS IP). The potential sites are studied on the basis of (a) expectations for neutrino interaction rates, flavour composition and energy spectrum, (b) predicted backgrounds and in-situ measurements, performed with a nuclear emulsion detector and radiation monitors. TI18 emerges as the most favourable location. A small detector in TI18 could measure, for the first time, the high-energy $\nu$N cross section, and separately for $\tau$ neutrinos, with good precision, already with 300 fb$^{-1}$ in the LHC Run3.
id cern-2665801
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2019
record_format invenio
spelling cern-26658012022-08-10T12:27:30Zdoi:10.1088/1361-6471/ab3f7chttp://cds.cern.ch/record/2665801engBeni, N.Brucoli, M.Buontempo, S.Cafaro, V.Dallavalle, G.M.Danzeca, S.De Lellis, G.Di Crescenzo, A.Giordano, V.Guandalini, C.Lazic, D.Lo Meo, S.Navarria, F.L.Szillasi, Z.Physics Potential of an Experiment using LHC NeutrinosDetectors and Experimental Techniquesphysics.ins-dethep-exParticle Physics - ExperimentProduction of neutrinos is abundant at LHC. Flavour composition and energy reach of the neutrino flux from proton-proton collisions depend on the pseudorapidity $\eta$. At large $\eta$, energies can exceed the TeV, with a sizeable contribution of the $\tau$ flavour. A dedicated detector could intercept this intense neutrino flux in the forward direction, and measure the interaction cross section on nucleons in the unexplored energy range from a few hundred GeV to a few TeV. The high energies of neutrinos result in a larger $\nu$N interaction cross section, and the detector size can be relatively small. Machine backgrounds vary rapidly while moving along and away from the beam line. Four locations were considered as hosts for a neutrino detector: the CMS quadruplet region (~25 m from CMS Interaction Point (IP)), UJ53 and UJ57 (90 and 120 m from CMS IP), RR53 and RR57 (240 m from CMS IP), TI18 (480 m from ATLAS IP). The potential sites are studied on the basis of (a) expectations for neutrino interaction rates, flavour composition and energy spectrum, (b) predicted backgrounds and in-situ measurements, performed with a nuclear emulsion detector and radiation monitors. TI18 emerges as the most favourable location. A small detector in TI18 could measure, for the first time, the high-energy $\nu$N cross section, and separately for $\tau$ neutrinos, with good precision, already with 300 fb$^{-1}$ in the LHC Run3.Neutrinos are abundantly produced in the LHC. Flavour composition and energy reach of the neutrino flux from proton–proton collisions depend on the pseudorapidity η. At large η, energies can exceed the TeV, with a sizeable contribution of the τ flavour. A dedicated detector could intercept this intense neutrino flux in the forward direction, and measure the interaction cross section on nucleons in the unexplored energy range from a few hundred GeV to a few TeV. The high energies of neutrinos result in a larger νN interaction cross section, and the detector size can be relatively small. Machine backgrounds vary rapidly while moving along and away from the beam line. Four locations were considered as hosts for a neutrino detector: the CMS quadrupole region (25 m from CMS Interaction Point (IP)), UJ53 and UJ57 (90 and 120 m from CMS IP), RR53 and RR57 (240 m from CMS IP), TI18 (480 m from ATLAS IP). The potential sites are studied on the basis of (a) expectations for neutrino interaction rates, flavour composition and energy spectrum, (b) predicted backgrounds and in situ measurements, performed with a nuclear emulsion detector and radiation monitors. TI18 emerges as the most favourable location. Already with 150 fb−1 expected in LHC Run3, a small detector in TI18 could measure, for the first time and with good precision, the high-energy νN cross section for all neutrino flavours.Production of neutrinos is abundant at LHC. Flavour composition and energy reach of the neutrino flux from proton-proton collisions depend on the pseudorapidity $\eta$. At large $\eta$, energies can exceed the TeV, with a sizeable contribution of the $\tau$ flavour. A dedicated detector could intercept this intense neutrino flux in the forward direction, and measure the interaction cross section on nucleons in the unexplored energy range from a few hundred GeV to a few TeV. The high energies of neutrinos result in a larger $\nu$N interaction cross section, and the detector size can be relatively small. Machine backgrounds vary rapidly while moving along and away from the beam line. Four locations were considered as hosts for a neutrino detector: the CMS quadruplet region (~25 m from CMS Interaction Point (IP)), UJ53 and UJ57 (90 and 120 m from CMS IP), RR53 and RR57 (240 m from CMS IP), TI18 (480 m from ATLAS IP). The potential sites are studied on the basis of (a) expectations for neutrino interaction rates, flavour composition and energy spectrum, (b) predicted backgrounds and in-situ measurements, performed with a nuclear emulsion detector and radiation monitors. TI18 emerges as the most favourable location. A small detector in TI18 could measure, for the first time, the high-energy $\nu$N cross section, and separately for $\tau$ neutrinos, with good precision, already with 300 fb$^{-1}$ in the LHC Run3.arXiv:1903.06564CMS-NOTE-2019-001CERN-CMS-NOTE-2019-001oai:cds.cern.ch:26658012019-03-05
spellingShingle Detectors and Experimental Techniques
physics.ins-det
hep-ex
Particle Physics - Experiment
Beni, N.
Brucoli, M.
Buontempo, S.
Cafaro, V.
Dallavalle, G.M.
Danzeca, S.
De Lellis, G.
Di Crescenzo, A.
Giordano, V.
Guandalini, C.
Lazic, D.
Lo Meo, S.
Navarria, F.L.
Szillasi, Z.
Physics Potential of an Experiment using LHC Neutrinos
title Physics Potential of an Experiment using LHC Neutrinos
title_full Physics Potential of an Experiment using LHC Neutrinos
title_fullStr Physics Potential of an Experiment using LHC Neutrinos
title_full_unstemmed Physics Potential of an Experiment using LHC Neutrinos
title_short Physics Potential of an Experiment using LHC Neutrinos
title_sort physics potential of an experiment using lhc neutrinos
topic Detectors and Experimental Techniques
physics.ins-det
hep-ex
Particle Physics - Experiment
url https://dx.doi.org/10.1088/1361-6471/ab3f7c
http://cds.cern.ch/record/2665801
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