The lhcf detector at the cern large hadron collider

O. Adriani; L. Bonechi; M. Bongi; G. Castellini; R. D'Alessandro; D. A. Faus; K. Fukui; M. Grandi; M. Haguenauer; Y. Itow; K. Kasahara; D. Macina; T. Mase; K. Masuda; Y. Matsubara; H. Menjo; M. Mizuishi; Y. Muraki; P. Papini; A. L. Perrot; S. Ricciarini; T. Sako; Y. Shimizu; K. Taki; T. Tamura; S. Torii; A. Tricomi; W. C. Turner; J. Velasco; A. Viciani; H. Watanabe; K. Yoshida

doi:10.1088/1748-0221/3/08/S08006

The lhcf detector at the cern large hadron collider

O. Adriani, L. Bonechi, M. Bongi, G. Castellini, R. D'Alessandro, D. A. Faus, K. Fukui, M. Grandi, M. Haguenauer, Y. Itow, K. Kasahara, D. Macina, T. Mase, K. Masuda, Y. Matsubara, H. Menjo, M. Mizuishi, Y. Muraki, P. Papini, A. L. PerrotS. Ricciarini, T. Sako, Y. Shimizu, K. Taki, T. Tamura, S. Torii, A. Tricomi, W. C. Turner, J. Velasco, A. Viciani, H. Watanabe, K. Yoshida

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Abstract

LHCf is an experiment dedicated to the measurement of neutral particles emitted in the very forward region of LHC collisions. The physics goal is to provide data for calibrating the hadron interaction models that are used in the study of Extremely High-Energy Cosmic-Rays. This is possible since the laboratory equivalent collision energy of LHC is 10¹⁷ eV. Two LHCf detectors, consisting of imaging calorimeters made of tungsten plates, plastic scintillator and position sensitive sensors, are installed at zero degree collision angle ±140 m from an interaction point (IP). Although the lateral dimensions of these calorimeters are very compact, ranging from 20 mmx20 mm to 40 mmx40 mm, the energy resolution is expected to be better than 6% and the position resolution better than 0.2 mm for γ-rays with energy from 100 GeV to 7 TeV. This has been confirmed by test beam results at the CERN SPS. These calorimeters can measure particles emitted in the pseudo rapidity range n >8.4. Detectors, data acquisition and electronics are optimized to operate during the early phase of the LHC commissioning with luminosity below 10 ³⁰ cm^-2s^-1. LHCf is expected to obtain data to compare with the major hadron interaction models within a week or so of operation at luminosity ∼ 10²⁹ cm^-2s^-1. After ∼10 days of operation at luminosity <∼-410²⁹cm ^-2s^-1, the light output of the plastic scintillators is expected to degrade by ∼10% due to radiation damage. This degradation will be monitored and corrected for using calibration pulses from a laser.

Original language	English
Article number	S08006
Journal	Journal of Instrumentation
Volume	3
Issue number	8
DOIs	https://doi.org/10.1088/1748-0221/3/08/S08006
Publication status	Published - 2008

Keywords

Analysis and statistical methods
Calorimeters
Data acquisition concepts
Detector alignment and calibration methods
Detector control systems
Front-end electronics for detector readout
Gamma detectors
Overall mechanics design
Particle detectors
Particle identification methods
Particle tracking detectors
Pattern recognition, cluster finding, calibration and fitting methods
Photon detectors for UV, visible and IR photons
Radiation damage to detector materials
Scintillators and scintillating fibers and light guides
Scintillators, scintillation and light emission processes
Simulation methods and programs
Solid state detectors
Trigger concepts and systems

ASJC Scopus subject areas

Instrumentation
Mathematical Physics

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10.1088/1748-0221/3/08/S08006

Cite this

Adriani, O., Bonechi, L., Bongi, M., Castellini, G., D'Alessandro, R., Faus, D. A., Fukui, K., Grandi, M., Haguenauer, M., Itow, Y., Kasahara, K., Macina, D., Mase, T., Masuda, K., Matsubara, Y., Menjo, H., Mizuishi, M., Muraki, Y., Papini, P., ... Yoshida, K. (2008). The lhcf detector at the cern large hadron collider. Journal of Instrumentation, 3(8), [S08006]. https://doi.org/10.1088/1748-0221/3/08/S08006

Adriani, O, Bonechi, L, Bongi, M, Castellini, G, D'Alessandro, R, Faus, DA, Fukui, K, Grandi, M, Haguenauer, M, Itow, Y, Kasahara, K, Macina, D, Mase, T, Masuda, K, Matsubara, Y, Menjo, H, Mizuishi, M, Muraki, Y, Papini, P, Perrot, AL, Ricciarini, S, Sako, T, Shimizu, Y, Taki, K, Tamura, T, Torii, S, Tricomi, A, Turner, WC, Velasco, J, Viciani, A, Watanabe, H & Yoshida, K 2008, 'The lhcf detector at the cern large hadron collider', Journal of Instrumentation, vol. 3, no. 8, S08006. https://doi.org/10.1088/1748-0221/3/08/S08006

@article{08b2bb1c03b64c92ab5f7b8523ec5cab,

title = "The lhcf detector at the cern large hadron collider",

abstract = "LHCf is an experiment dedicated to the measurement of neutral particles emitted in the very forward region of LHC collisions. The physics goal is to provide data for calibrating the hadron interaction models that are used in the study of Extremely High-Energy Cosmic-Rays. This is possible since the laboratory equivalent collision energy of LHC is 1017 eV. Two LHCf detectors, consisting of imaging calorimeters made of tungsten plates, plastic scintillator and position sensitive sensors, are installed at zero degree collision angle ±140 m from an interaction point (IP). Although the lateral dimensions of these calorimeters are very compact, ranging from 20 mmx20 mm to 40 mmx40 mm, the energy resolution is expected to be better than 6% and the position resolution better than 0.2 mm for γ-rays with energy from 100 GeV to 7 TeV. This has been confirmed by test beam results at the CERN SPS. These calorimeters can measure particles emitted in the pseudo rapidity range n >8.4. Detectors, data acquisition and electronics are optimized to operate during the early phase of the LHC commissioning with luminosity below 10 30 cm-2s-1. LHCf is expected to obtain data to compare with the major hadron interaction models within a week or so of operation at luminosity ∼ 1029 cm-2s-1. After ∼10 days of operation at luminosity <∼-41029cm -2s-1, the light output of the plastic scintillators is expected to degrade by ∼10% due to radiation damage. This degradation will be monitored and corrected for using calibration pulses from a laser.",

keywords = "Analysis and statistical methods, Calorimeters, Data acquisition concepts, Detector alignment and calibration methods, Detector control systems, Front-end electronics for detector readout, Gamma detectors, Overall mechanics design, Particle detectors, Particle identification methods, Particle tracking detectors, Pattern recognition, cluster finding, calibration and fitting methods, Photon detectors for UV, visible and IR photons, Radiation damage to detector materials, Scintillators and scintillating fibers and light guides, Scintillators, scintillation and light emission processes, Simulation methods and programs, Solid state detectors, Trigger concepts and systems",

author = "O. Adriani and L. Bonechi and M. Bongi and G. Castellini and R. D'Alessandro and Faus, {D. A.} and K. Fukui and M. Grandi and M. Haguenauer and Y. Itow and K. Kasahara and D. Macina and T. Mase and K. Masuda and Y. Matsubara and H. Menjo and M. Mizuishi and Y. Muraki and P. Papini and Perrot, {A. L.} and S. Ricciarini and T. Sako and Y. Shimizu and K. Taki and T. Tamura and S. Torii and A. Tricomi and Turner, {W. C.} and J. Velasco and A. Viciani and H. Watanabe and K. Yoshida",

year = "2008",

doi = "10.1088/1748-0221/3/08/S08006",

language = "English",

volume = "3",

journal = "Journal of Instrumentation",

issn = "1748-0221",

publisher = "IOP Publishing Ltd.",

number = "8",

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TY - JOUR

T1 - The lhcf detector at the cern large hadron collider

AU - Adriani, O.

AU - Bonechi, L.

AU - Bongi, M.

AU - Castellini, G.

AU - D'Alessandro, R.

AU - Faus, D. A.

AU - Fukui, K.

AU - Grandi, M.

AU - Haguenauer, M.

AU - Itow, Y.

AU - Kasahara, K.

AU - Macina, D.

AU - Mase, T.

AU - Masuda, K.

AU - Matsubara, Y.

AU - Menjo, H.

AU - Mizuishi, M.

AU - Muraki, Y.

AU - Papini, P.

AU - Perrot, A. L.

AU - Ricciarini, S.

AU - Sako, T.

AU - Shimizu, Y.

AU - Taki, K.

AU - Tamura, T.

AU - Torii, S.

AU - Tricomi, A.

AU - Turner, W. C.

AU - Velasco, J.

AU - Viciani, A.

AU - Watanabe, H.

AU - Yoshida, K.

PY - 2008

Y1 - 2008

N2 - LHCf is an experiment dedicated to the measurement of neutral particles emitted in the very forward region of LHC collisions. The physics goal is to provide data for calibrating the hadron interaction models that are used in the study of Extremely High-Energy Cosmic-Rays. This is possible since the laboratory equivalent collision energy of LHC is 1017 eV. Two LHCf detectors, consisting of imaging calorimeters made of tungsten plates, plastic scintillator and position sensitive sensors, are installed at zero degree collision angle ±140 m from an interaction point (IP). Although the lateral dimensions of these calorimeters are very compact, ranging from 20 mmx20 mm to 40 mmx40 mm, the energy resolution is expected to be better than 6% and the position resolution better than 0.2 mm for γ-rays with energy from 100 GeV to 7 TeV. This has been confirmed by test beam results at the CERN SPS. These calorimeters can measure particles emitted in the pseudo rapidity range n >8.4. Detectors, data acquisition and electronics are optimized to operate during the early phase of the LHC commissioning with luminosity below 10 30 cm-2s-1. LHCf is expected to obtain data to compare with the major hadron interaction models within a week or so of operation at luminosity ∼ 1029 cm-2s-1. After ∼10 days of operation at luminosity <∼-41029cm -2s-1, the light output of the plastic scintillators is expected to degrade by ∼10% due to radiation damage. This degradation will be monitored and corrected for using calibration pulses from a laser.

AB - LHCf is an experiment dedicated to the measurement of neutral particles emitted in the very forward region of LHC collisions. The physics goal is to provide data for calibrating the hadron interaction models that are used in the study of Extremely High-Energy Cosmic-Rays. This is possible since the laboratory equivalent collision energy of LHC is 1017 eV. Two LHCf detectors, consisting of imaging calorimeters made of tungsten plates, plastic scintillator and position sensitive sensors, are installed at zero degree collision angle ±140 m from an interaction point (IP). Although the lateral dimensions of these calorimeters are very compact, ranging from 20 mmx20 mm to 40 mmx40 mm, the energy resolution is expected to be better than 6% and the position resolution better than 0.2 mm for γ-rays with energy from 100 GeV to 7 TeV. This has been confirmed by test beam results at the CERN SPS. These calorimeters can measure particles emitted in the pseudo rapidity range n >8.4. Detectors, data acquisition and electronics are optimized to operate during the early phase of the LHC commissioning with luminosity below 10 30 cm-2s-1. LHCf is expected to obtain data to compare with the major hadron interaction models within a week or so of operation at luminosity ∼ 1029 cm-2s-1. After ∼10 days of operation at luminosity <∼-41029cm -2s-1, the light output of the plastic scintillators is expected to degrade by ∼10% due to radiation damage. This degradation will be monitored and corrected for using calibration pulses from a laser.

KW - Analysis and statistical methods

KW - Calorimeters

KW - Data acquisition concepts

KW - Detector alignment and calibration methods

KW - Detector control systems

KW - Front-end electronics for detector readout

KW - Gamma detectors

KW - Overall mechanics design

KW - Particle detectors

KW - Particle identification methods

KW - Particle tracking detectors

KW - Pattern recognition, cluster finding, calibration and fitting methods

KW - Photon detectors for UV, visible and IR photons

KW - Radiation damage to detector materials

KW - Scintillators and scintillating fibers and light guides

KW - Scintillators, scintillation and light emission processes

KW - Simulation methods and programs

KW - Solid state detectors

KW - Trigger concepts and systems

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UR - http://www.scopus.com/inward/citedby.url?scp=65649121715&partnerID=8YFLogxK

U2 - 10.1088/1748-0221/3/08/S08006

DO - 10.1088/1748-0221/3/08/S08006

M3 - Article

AN - SCOPUS:65649121715

SN - 1748-0221

VL - 3

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 8

M1 - S08006

ER -

The lhcf detector at the cern large hadron collider

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Keywords

ASJC Scopus subject areas

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