First test-beam results obtained with IDEA, a detector concept designed for future lepton colliders

Aly, R.; Antonello, M.; Azzi, P.; Bedeschi, F.; Bencivenni, G.; Borgonovi, L.; Caccia, M.; Chu, X.; Cibinetto, G.; Coates, Thomas D.; Cussans, D.; Filippis, N. De; Santo, A. De; Dünser, M.; Eté, Rémi; Farinelli, R.; Ferrari, R.; Fontanesi, E.; Franchino, S.; Gaudio, G.; Giacomelli, P.; Grancagnolo, F.; Gribanov, S.S.; Hauptman, J. M.; Janot, P.; Jones, S.; Lee, K.; Lee, S.; Lerner, G.; Morello, G.; Nam, K.; Pezzotti, L.; Pingault, Antoine; Lener, M. Poli; Popov, Andrey; Salvatore, F.; Santoro, R.; Taliercio, A.; Tassielli, G.; Testa, B.; Vivarelli, I.; Wigmans, R.

doi:10.1016/j.nima.2019.04.042

Cited by 9 publications

(9 citation statements)

References 5 publications

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“…LYSO crystals, to allow precise particle identification for the b physics program at high intensity running at the Z pole and to remove beam backgrounds at muon colliders. A preliminary implementation of the segmented crystal calorimeter geometry with the IDEA detector [43] is shown in Figure 14 [right]. Previous calorimeter systems with a crystal EM calorimeter and a conventional sampling hadron calorimeter, such as the CMS experiment, have had very poor hadronic resolution due to the mismatch between the ratio of their responses to the electromagnetic and hadronic portions of a hadron-initiated shower (e/h).…”

Section: Dual Readout With Crystal Calorimetersmentioning

confidence: 99%

Dual-Readout Calorimetry for Future Experiments Probing Fundamental Physics

Pezzotti¹,

Newman²,

Freeman³

et al. 2022

Preprint

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In this White Paper for the 2021 Snowmass process, we detail the status and prospects for dual-readout calorimetry. While all calorimeters allow estimation of energy depositions in their active material, dual-readout calorimeters aim to provide additional information on the light produced in the sensitive media via, for example, wavelength and polarization, and/or a precision timing measurements, allowing an estimation of the shower-by-shower particle content. Utilizing this knowledge of the shower particle content may allow unprecedented energy resolution for hadronic particles and jets, and new types of particle flow algorithms. We also discuss the impact continued development of this kind of calorimetry could have on precision on Higgs boson property measurements at future colliders.

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Section: Dual Readout With Crystal Calorimetersmentioning

confidence: 99%

Dual-Readout Calorimetry for Future Experiments Probing Fundamental Physics

Pezzotti¹,

Newman²,

Freeman³

et al. 2022

Preprint

Self Cite

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“…Therefore many existing MPGD technologies are suitable for building future large muon detection systems. For example the µRWELL technology is envisaged to be utilized for the muon detection system and the preshower detector of the IDEA detector concept [26,33] that is proposed for the FCC-ee and CepC future large circular leptonic colliders. In addition µRWELL are candidates for the inner tracking system at future high luminosity tau-charm factories, STCF in Russia and SCTF in China.…”

Section: Executive Summarymentioning

confidence: 99%

“…This detector is therefore an ideal candidate to be the technology of choice for building future large muon detection systems [87,88]. The µRWELL technology is in fact envisaged to realise the muon detection system and the preshower of the IDEA detector concept [33] that is proposed for the FCC-ee [26] and CEPC [30] future large circular leptonic colliders.…”

Section: Muon Tracking At Fcc-ee and Cepcmentioning

confidence: 99%

MPGDs for tracking and Muon detection at future high energy physics colliders

Black¹,

Colaleo²,

Aimè³

et al. 2022

Preprint

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“…The performance, in the reconstruction of the properties of both hadronic and EM showers, is good enough to open the possibility to exploit a single integrated dual-readout fibresampling solution, for the calorimetric system of an FCC-ee experiment. This is the baseline choice in the IDEA [44] detector concept.…”

Section: Arbitrary Unitsmentioning

confidence: 99%

Calorimetry at FCC-ee

et al. 2021

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With centre-of-mass energies covering the Z pole, the WW threshold, the HZ production, and the top-pair threshold, the FCC-ee offers unprecedented possibilities to measure the properties of the four heaviest particles of the standard model (the Higgs, Z, and W bosons, and the top quark) and also those of the b and c quarks and of the $$\tau $$ τ lepton. At these moderate energies, the role of the calorimeters is to complement the tracking systems in an optimal (a.k.a. particle-flow) event reconstruction. In this context, precision measurements and searches for new particles can fully profit from the improved electromagnetic and hadronic object reconstruction offered by new technologies, finer transverse and longitudinal segmentation, timing capabilities, multi-signal readout, modern computing techniques and algorithms. The corresponding requirements arise in particular from the resolution on reconstructed hadronic masses, energies, and momenta, for example, of H, W, Z, needed to reach the FCC-ee promised precision. Extreme electromagnetic energy resolutions are also instrumental for $$\pi ^0$$ π 0 identification, $$\tau $$ τ exclusive decay reconstruction, and physics sensitivity to processes accessible via radiative return. We present state of the art, challenges and future developments on some of the currently most promising technologies: high-granularity silicon and scintillator readout, dual readout, noble-liquid and crystal calorimeters.

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First test-beam results obtained with IDEA, a detector concept designed for future lepton colliders

Cited by 9 publications

References 5 publications

Dual-Readout Calorimetry for Future Experiments Probing Fundamental Physics

Dual-Readout Calorimetry for Future Experiments Probing Fundamental Physics

MPGDs for tracking and Muon detection at future high energy physics colliders

Calorimetry at FCC-ee

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