Test beam characterization of sensor prototypes for the CMS Barrel MIP   Timing Detector

R. Abbott; A. Abreu; F. Addesa; M. Alhusseini; T. Anderson; Y.; Andreev; A. Apresyan; R. Arcidiacono; M. Arenton; E. Auffray; D. Bastos,; L.A.T. Bauerdick; R. Bellan; M. Bellato; A. Benaglia; M. Benettoni; R.; Bertoni; M. Besancon; S. Bharthuar; A. Bornheim; E. Br\"ucken; J.N. Butler,; C. Campagnari; M. Campana; R. Carlin; P. Carniti; N. Cartiglia; M. Casarsa,; O. Cerri; P. Checchia; H. Chen; S. Chidzik; F. Chlebana; F. Cossutti; M.; Costa; B. Cox; I. Dafinei; F. De Guio; P. Debbins; D. del Re; A. Dermenev; E.; Di Marco; K. Dilsiz; K.F. Di Petrillo; G. Dissertori; S. Dogra; U. Dosselli,; I. Dutta; F. Caleb; C. Fernandez Madrazo; M. Fernandez; M. Ferrero; Z.; Flowers; W. Funk; M. Gallinaro; S. Ganjour; M. Gardner; F. Geurts; A. Ghezzi,; S. Gninenko; F. Golf; J. Gonzalez; C. Gotti; L. Gray; F. Guilloux; S.; Gundacker; E. Hazen; S. Hedia; A. Heering; R. Heller; T. Isidori; R.; Isocrate; R. Jaramillo; M. Joyce; K. Kaadze; A. Karneyeu; H. Kim; J. King; G.; Kopp; M. Korjik; O. K. Koseyan; A. Kozyrev; N. Kratochwil; M. Lazarovits; A.; Ledovskoy; H. Lee; J. Lee; A. Li; S. Li; W. Li; T. Liu; N. Lu; M. Lucchini,; W. Lustermann; C. Madrid; M. Malberti; I. Mandjavize; J. Mao; Y. Maravin; D.; Marlow; B. Marsh; P. Martinez del Arbol; B. Marzocchi; R. Mazza; C. McMahon,; V. Mechinsky; P. Meridiani; A. Mestvirishvili; N. Minafra; A. Mohammadi; F.; Monti; C.S. Moon; R. Mulargia; M. Murray; Y. Musienko; J. Nachtman; S.; Nargelas; L. Narvaez; O. Neogi; C. Neu; T. Niknejad; M. Obertino; H. Ogul; G.; Oh; I. Ojalvo; Y. Onel; G. Organtini; T. Orimoto; J. Ott; I. Ovtin; M.; Paganoni; F. Pandolfi; R. Paramatti; A. Peck; C. Perez; G. Pessina; C. Pena,; S. Pigazzini; O. Radchenko; N. Redaelli; D. Rigoni; E. Robutti; C. Rogan; R.; Rossin; C. Rovelli; C. Royon; M.\"O. Sahin; W. Sands; F. Santanastasio; U.; Sarica; I. Schmidt; R. Schmitz; J. Sheplock; J. C. Silva; F. Siviero; L.; Soffi; V. Sola; G. Sorrentino; M. Spiropulu; D. Spitzbart; A. G. Stahl; Leiton; A. Staiano; D. Stuart; I. Suarez; T. Tabarelli de Fatis; G.; Tamulaitis; Y. Tang; B. Tannenwald; R. Taylor; E. Tiras; M. Titov; S.; Tkaczyk; D. Tlisov; I. Tlisova; M. Tornago; M. Tosi; R. Tramontano; J.; Trevor; C.G. Tully; B. Ujvari; J. Varela; S. Ventura; I. Vila; T. Wamorkar,; C. Wang; X. Wang; M. Wayne; J. Wetzel; S. White; D. Winn; S. Wu; S. Xie; Z.; Ye; G.B. Yu; G. Zhang; L. Zhang; Y. Zhang; Z. Zhang; R. Zhu

arXiv:2104.07786·physics.ins-det·July 19, 2021

Test beam characterization of sensor prototypes for the CMS Barrel MIP Timing Detector

R. Abbott, A. Abreu, F. Addesa, M. Alhusseini, T. Anderson, Y., Andreev, A. Apresyan, R. Arcidiacono, M. Arenton, E. Auffray, D. Bastos,, L.A.T. Bauerdick, R. Bellan, M. Bellato, A. Benaglia, M. Benettoni, R., Bertoni, M. Besancon, S. Bharthuar, A. Bornheim, E. Br\"ucken

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TL;DR

This study evaluates the timing performance of sensor prototypes for the CMS Barrel MIP Timing Detector using test beam measurements, demonstrating a time resolution around 22-28 ps with unirradiated sensors, supporting detector design choices.

Contribution

The paper presents the first test beam characterization of elongated crystal bar sensors with double-ended SiPM readout for the CMS MIP Timing Detector, validating their timing performance.

Findings

01

Achieved ~22-28 ps time resolution with unirradiated sensors.

02

Validated the robustness of the double-ended readout design.

03

Confirmed the sensor performance meets the detector requirements.

Abstract

The MIP Timing Detector will provide additional timing capabilities for detection of minimum ionizing particles (MIPs) at CMS during the High Luminosity LHC era, improving event reconstruction and pileup rejection. The central portion of the detector, the Barrel Timing Layer (BTL), will be instrumented with LYSO:Ce crystals and Silicon Photomultipliers (SiPMs) providing a time resolution of about 30 ps at the beginning of operation, and degrading to 50-60 ps at the end of the detector lifetime as a result of radiation damage. In this work, we present the results obtained using a 120 GeV proton beam at the Fermilab Test Beam Facility to measure the time resolution of unirradiated sensors. A proof-of-concept of the sensor layout proposed for the barrel region of the MTD, consisting of elongated crystal bars with dimensions of about 3 x 3 x 57 mm $^{3}$ and with double-ended SiPM readout, is…

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