Hadronic energy resolution of a highly granular scintillator-steel hadron calorimeter using software compensation techniques

Adloff, C.; Blaha, J.; Blaising, J. J.; Drancourt, C.; Espargilière, A.; Gaglione, R.; Geffroy, N.; Karyotakis, Y.; Prast, J.; Vouters, G.; Francis, K.; Repond, J.; Smith, Jacob; Xia, L.; Baldolemar, E.; Li, J; Park, S T; Sosebee, M.; White, A.; Yu, J.; Buanes, T.; Eigen, G.; Mikami, Y.; Watson, N. K.; Goto, Toru; Mavromanolakis, G.; Thomson, M. A.; Ward, D. R.; Yan, W.; Benchekroun, D.; Hoummada, A.; Khoulaki, Y.; Benyamna, M.; Cârloganu, C.; Fehr, F.; Manen, S.; Royer, L.; Blazey, G.; Dyshkant, A.; Lima, J. G. Rocha de; Zutshi, V.; Hostachy, J-Y.; Morin, Laurent; Cornett, U.; David, D.; Falley, G.; Gadow, Karsten; Göttlicher, P.; Günter, C.; Hermberg, B.; Karstensen, S.; Kriváň, F.; Lucaci-Timoce, A.-I.; Lu, Shaojun; Lutz, B.; Morozov, S. V.; Morgunov, V.; Reinecke, Mathias; Sefkow, F.; Smirnov, P.; Terwort, M.; Vargas-Trevino, A.; Feege, N.; Garutti, E.; Marchesini, I.; Ramilli, Marco; Eckert, P.; Harion, Tobias; Kaplan, A.; Schultz‐Coulon, H.‐C.; Shen, Wei; Stamen, R.; Tadday, A.; Bilki, B.; Norbeck, E.; Onel, Y.; Wilson, G. W.; Kawagoe, K.; Dauncey, P.; Magnan, A.-M.; Wing, M.; Salvatore, F.; Alamillo, Enrique Calvo; Fouz, M. C.; Pelayo, J. Puerta; Balagura, V.; Bobchenko, B.; Chadeeva, M.; Danilov, M.; Epifantsev, A.; Markin, O.; Mizuk, R.; Novikov, E.; Rusinov, V.; Tarkovsky, E.; Kirikova, N.; Kozlov, V.; Soloviev, Y.; Buzhan, P.; Dolgoshein, B. A.; Ilyin, A.; Kantserov, V. A.; Kaplin, V.; Karakash, A.; Popova, E.; Smirnov, S. Yu.; Kiesling, C.; Pfau, S; Seidel, K.; Simon, F.; Soldner, C.; Szalay, Marco; Tesar, M.; Weuste, L.; Bonis, J.; Bouquet, B.; Callier, S.; Cornebise, P.; Doublet, Ph.; Dulucq, F.; Giannelli, M. Faucci; Fleury, J.; Li, H; Martin-Chassard, Gisèle; Richard, F.; Taille, C. De La; Pöschl, R.; Raux, L.; Seguin-Moreau, N.; Wicek, F.; Anduze, Marc; Boudry, V.; Brient, J. C.; Jeans, D.; Freitas, P. Mora de; Musat, G.; Reinhard, Marcel; Ruan, Manqi; Videau, H.; Bulanek, B.; Žáček, J.; Cvach, J.; Gallus, P.; Havránek, M.; Janata, M.; Kvasnička, J; Lednický, D.; Marčišovský, M.; Polák, Ivo; Popule, J.; Tomášek, L.; Tomášek, M.; Růžička, P.; Šı́cho, P.; Smolík, J.; Vrba, V.; Zálešâk, J.; Belhorma, B.; Ghazlane, H.; Takeshita, T.; Uozumi, S.; Sauer, J.R.; Weber, Sebastian Mario; Zeitnitz, C.

doi:10.1088/1748-0221/7/09/p09017

Cited by 56 publications

(82 citation statements)

References 27 publications

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“…The linearity and the energy resolution -a key performance parameter even for a particle flow detector -of the AHCAL have been studied using pion beam at di erent energies [315]. In Figure III- 3.18(left) the reconstructed single particle energy is shown as a function of the beam energy.…”

Section: Ahcal Test Beam Results and Operational Experiencementioning

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: Ahcal Test Beam Results and Operational Experiencementioning

confidence: 99%

“…The hadronic response for the AHCAL shows small deviations from linearity (less than 2% up to 80 GeV), mainly due to the non-compensating features of the structure (e/fi ≥ 1.19) [315] and to leakage. It can be predicted by simulations and was verified with test beam data.…”

Section: Energy Scalesmentioning

confidence: 94%

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

Behnke

2013

178

200

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“…This saturation effect is addressed by the cellby-cell application of a correction algorithm which gives the expected true number of photons for a given number of fired SiPM pixels, as discussed in detail in [8], resulting in the recovery of a linear response of the calorimeter over a wide energy range. While the uncertainty of this saturation correction is the leading systematic in the energy reconstruction for electromagnetic showers of 40 GeV and above [8], it was found to be negligible for hadronic showers at all energies [9]. With local software compensation techniques used for energy reconstruction, the prototype achieved a hadronic energy resolution of ∼ 44%/ √ E[GeV] ⊕ 1.8% [9], with a response within 1.5% of linearity.…”

Section: Pioneering Experiments: Calice and T2kmentioning

confidence: 99%

“…While the uncertainty of this saturation correction is the leading systematic in the energy reconstruction for electromagnetic showers of 40 GeV and above [8], it was found to be negligible for hadronic showers at all energies [9]. With local software compensation techniques used for energy reconstruction, the prototype achieved a hadronic energy resolution of ∼ 44%/ √ E[GeV] ⊕ 1.8% [9], with a response within 1.5% of linearity. Following the successful tests of the CALICE AHCAL physics prototype, the technology for highly granular scintillator-based calorimeters was further developed, as discussed in Section 3.3.…”

Section: Pioneering Experiments: Calice and T2kmentioning

confidence: 99%

Silicon photomultipliers in particle and nuclear physics

Simon

2019

Nuclear Instruments and Methods in Physics Research Section A:

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Following first large-scale applications in highly granular calorimeters and in neutrino detectors, Silicon Photomultipliers have seen a wide adoption in accelerator-based particle and nuclear physics experiments. Today, they are used for a wide range of different particle detector types, ranging from calorimeters and trackers to particle identification and veto detectors, large volume detectors for neutrino physics and timing systems. This article reviews the current state and expected evolution of these applications, highlighting strengths and limitation of SiPMs and the corresponding design choices in the respective contexts. General trends and adopted technical solutions in the applications are discussed.

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“…Most importantly, the AHCAL validated procedures for channel calibration and monitoring that account for the non-linear and T-dependent response of SiPMs. Also, it demonstrated powerful compensation techniques based on the energy density to reduce the shower stochastic fluctuations from 58%/ √ E to 45%/ √ E [14] while keeping a constant term smaller than 2 % (Fig. 2 left).…”

Section: Hadronic Calorimetersmentioning

confidence: 99%

Development of highly granular calorimeters in CALICE

Chefdeville¹

2014

Proceedings of the European Physical Society Conference on High Energy Physics — PoS(EPS-HEP 2013)

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The design of calorimeter systems for a detector at a future e + e − Linear Collider (ILC, CLIC) is largely driven by the requirements of jet reconstruction. The particle flow technique has been shown to be capable of achieving an energy resolution ∼ 30% / √ E, permitting the discrimination of W and Z bosons in their hadronic decays. Such performance requires the separation of neutral and charged energy deposits in the calorimeters, which in turn demands that they have high spatial granularity both transversely and longitudinally, and be placed within the magnet coil. The CALICE collaboration has been developing prototype calorimeters to meet these requirements. The electromagnetic calorimeter is based on tungsten absorbers and active layers of silicon pads of ∼ 5×5 mm 2 and/or crossed short scintillator strips of ∼ 5×45 mm 2 . The hadronic calorimeter could use iron or tungsten absorbers, sampled using either scintillator tiles of ∼ 3×3 cm 2 or gaseous detectors with ∼ 1×1 cm 2 readout. The scintillator option uses an analogue readout, while the gas detectors (RPCs, Micromegas or GEMs) use either digital (1 bit) or semi-digital (2 bit) readout. All these options are being pursued in CALICE. Key issues include: extreme compactness, hermeticity and scalability, power cycling and precise timing. We report on recent R&D and test beam activities from CALICE which address all these key questions.

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Hadronic energy resolution of a highly granular scintillator-steel hadron calorimeter using software compensation techniques

Cited by 56 publications

References 27 publications

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

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

Silicon photomultipliers in particle and nuclear physics

Development of highly granular calorimeters in CALICE

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