Forward instrumentation for ILC detectors

Abramowicz, H.; Abusleme, Angel; Afanaciev, K.; Aguilar, J. A.; Ambalathankandy, Prasoon; Bambade, P.; Bergholz, M.; Božović-Jelisavc̆ić, I.; Castro, E.; Chelkov, G.; Coca, C.; Daniluk, W.; Dragone, A.; Dumitru, Laurentiu Alexandru; Elsener, K.; Emeliantchik, I.; Fiutowski, T.; Gostkin, M. I.; Grah, Christian; Grzelak, G.; Haller, G.; Henschel, H.; Ignatenko, Alexandr; Idzik, M.; Ito, K.; Jovin, T.; Kielar, E.; Kotuła, J.; Krumstein, Z.; Kulis, S.; Lange, W.; Lohmann, W.; Levy, A.; Moszczyński, A.; Nauenberg, U.; Novgorodova, O.; Ohlerich, M.; Orlandea, M.; Oleinik, Gleb; Oliwa, Krzysztof; Olshevski, A. G.; Pandurović, M.; Pawlik, B.; Przyborowski, D.; Sato, Y.; Sadeh, I.; Sailer, A.; Schmidt, R.; Schumm, B. A.; Schuwalow, Sergej; Smiljanić, I.; Świentek, K.; Takubo, Y.; Teodorescu, E.; Wierba, Wojciech; Yamamoto, H.; Zawiejski, L.; Zhang, J

doi:10.1088/1748-0221/5/12/p12002

Cited by 58 publications

(72 citation statements)

References 37 publications

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“…First, there is the so-called LumiCal to measure the luminosity with a precision of better than 10 ≠3 using Bhabha scattering as reference process, e + e ≠ ae e + e ≠ ("). Then there is the BeamCal, positioned adjacent to the beampipe, to provide a bunch-by-bunch luminosity estimate and a determination of the beam parameters [22]. A third calorimeter, GamCal, about 100 m downstream of the detector, will assist in beam-tuning.…”

Section: Forward Calorimetrymentioning

confidence: 99%

“…Two special calorimeters are foreseen in the very forward regions of the detector [324], denoted hereafter as LumiCal and BeamCal. LumiCal will measure the luminosity with a precision of better than 10 ≠3 at 500 GeV centre-of-mass energy 1 , and BeamCal will perform a bunch-by-bunch estimate of the luminosity and, supplemented by a pair monitor, assist beam tuning when included in a fast feedback system [325].…”

Section: Forward Calorimetrymentioning

confidence: 99%

“…In both calorimeters a robust electron and photon shower measurement is essential, making a small Molière radius preferable. Compact, cylindrical sandwich calorimeters using tungsten absorber disks of one radiation length thickness, interspersed with finely segmented silicon (LumiCal) or GaAs (BeamCal) sensor planes, as sketched in Figure III -3.24, are found to match the requirements [324]. For the innermost part of BeamCal, adjacent to the beam-pipes, also Chemical Vapour Deposition (CVD) diamond sensors are considered.…”

Section: Mechanical Conceptmentioning

confidence: 99%

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The International Linear Collider Technical Design Report - Volume 4: Detectors

Behnke

2013

178

200

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Section: Forward Calorimetrymentioning

confidence: 99%

Section: Forward Calorimetrymentioning

confidence: 99%

Section: Mechanical Conceptmentioning

confidence: 99%

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The International Linear Collider Technical Design Report - Volume 4: Detectors

Behnke

2013

178

200

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“…With the same selection, the fraction of the lost events due to the beamstrahlung and ISR gets reduced ≤ 0.5‰ [4] since this type of isolation cuts prefer events with the smaller energy losses (smaller β coll ). Taking into account other systematic effects as in [12], we prove that the overall uncertainty of the integral luminosity is ≤ 3‰ at ILC energies taking into account simulation dependent corrections and ≤ 5 ‰ if one corrects in a simulation independent manner.…”

Section: Physics Background At Ilcmentioning

confidence: 65%

Physics and detector studies with the very forward calorimeters at a future linear collider

Božović-Jelisavc̆ić¹,

Lukić²,

Smiljanić³

et al. 2013

Proceedings of 36th International Conference on High Energy Physics — PoS(ICHEP2012)

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The very forward region at a future e + e -collider will be instrumented with calorimeters dedicated primarily for precise measurement of the integral luminosity with the precision required at a percent (CLIC) or at a permille level (ILC). As the constraints on luminosity precision come from the physics programs at future linear colliders, physics and machinerelated systematic effects are discussed as the main sources of uncertainty in luminosity measurement.

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“…The region between 0.6°and 6.3°is instrumented with the two silicontungsten sampling calorimeters, LumiCal and BeamCal [27], for the luminosity measurement, beam-parameter control, as well as for the tagging of high-energy electrons escaping the main detector at low angles. Together with the very forward segments of the electromagnetic calorimeter covering the polar-angle region between 6.3°and 8°, it is possible to suppress the four-fermion SM background with the characteristic low-angle electron signature.…”

Section: The Clic_ild Detector Modelmentioning

confidence: 99%

Physics potential for the measurement of $${\sigma (H\nu \bar{\nu })\times \text {BR}(H\rightarrow \mu ^+\mu ^-)}$$ σ ( H ν ν ¯ ) × BR ( H → μ + μ - ) at the 1.4 TeV CLIC collider

Milutinović-Dumbelović

Božović-Jelisavc̆ić

Grefe

et al. 2015

Eur. Phys. J. C

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The future compact linear collider (CLIC) offers a possibility for a rich precision physics programme, in particular in the Higgs sector through the energy staging. This is the first paper addressing the measurement of the standard model Higgs boson decay into two muons at 1.4 TeV CLIC. With respect to similar studies at future linear colliders, this paper includes several novel contributions to the statistical uncertainty of the measurement. The latter includes the equivalent photon approximation employed to describe e + e − and eγ interactions whenever the virtuality of the mediated photon is smaller than 4 GeV and realistic forward electron tagging based on energy deposition maps in the forward calorimeters, as well as several processes with the Beamstrahlung photons that results in irreducible contribution to the signal. In addition, coincidence of the Bhabha scattering with the signal and background processes is considered, altering the signal selection efficiency. The study is performed using a fully simulated CLIC_ILD detector model. It is shown that the branching ratio for the Higgs decay into a pair of muons BR(H → μ + μ − ) times the Higgs production cross-section in W W -fusion σ (H νν) can be measured with 38 % statistical accuracy at √ s = 1.4 TeV, assuming an integrated luminosity of 1.5 ab −1 with unpolarised beams. If 80 % electron beam polarisation is considered, the statistical uncertainty of the measurement is reduced to 25 %. Systematic uncertainties are negligible in comparison to the statistical uncertainty.This work was carried out in the framework of the CLICdp collaboration. a

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Forward instrumentation for ILC detectors

Cited by 58 publications

References 37 publications

The International Linear Collider Technical Design Report - Volume 4: Detectors

The International Linear Collider Technical Design Report - Volume 4: Detectors

Physics and detector studies with the very forward calorimeters at a future linear collider

Physics potential for the measurement of $${\sigma (H\nu \bar{\nu })\times \text {BR}(H\rightarrow \mu ^+\mu ^-)}$$ σ ( H ν ν ¯ ) × BR ( H → μ + μ - ) at the 1.4 TeV CLIC collider

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