Evaluation of Timepix3 as a luminosity detector at LHC during 2018 pp collisions at s=13 TeV
- NázevTitle
- Evaluation of Timepix3 as a luminosity detector at LHC during 2018 pp collisions at s=13 TeVEvaluation of Timepix3 as a luminosity detector at LHC during 2018 pp collisions at s=13 TeV
- Druh výsledkuResult type
- Článek v časopiseJournal article
- AutořiAuthors
- B. Bergmann, P. Burian, E. David Bosne, C. Lesmes, S. Pospíšil, P. Smolyanskiy
- DOIDOI
- 10.1140/epjc/s10052-025-14631-x
- Časopis / citaceJournal / citation
- European Physical Journal C. 2025, 85(8), 1-15. ISSN 1434-6052.
- RokYear
- 2025
- JazykLanguage
- eng
- WoSWoS
- 001636511200003
- ScopusScopus
- 2-s2.0-105015498275
- RIVRIV
- RIV/68407700:21340/25:00385391!RIV26-GA0-21340___
- ProjektProject
- Identifikace částic v experimentech fysiky vysokych energií a ve vesmíru s pokročilými detekčními systémyParticle identification in high-energy physics experiments and space with advanced detection systems
AbstraktAbstract
Four Timepix3 detectors were installed in the ATLAS experiment at different positions to study their capabilities to measure luminosity during pp-collisions at sqrt(13) TeV in 2018. While the detectors were operated independently of the ATLAS triggering and acquisition scheme, continuous (dead-time free) measurement together with an orbit clock trigger allowed for synchronization with the LHC. The detectors benefit from a fine segmentation, a pixel pitch of 55 µm, and a per-pixel time resolution of 1.6 ns allowing for a high-quality track reconstruction and particle identification. One of the 500 µm thick silicon sensors was equipped with a 6LiF neutron converter, extending the particle identification capabilities. The installed system was used to study luminosity in different time frames: long term (run-by-run), short term (within a single run) and instantaneous (for each bunch crossing). For the long- and short-term luminosity, partly-independent algorithms: cluster and thermal neutron counting are proposed. A comprehensive analysis of the signal from induced radioactivity and its consecutive removal is presented together with a study demonstrating that the activation-corrected Timepix3 luminosity measurement provides good linearity with respect to the pile-up parameter. For measurement of the instantaneous luminosity, a cluster classification scheme was employed to decompose the measured response to the colliding bunch signal. Selecting a subset of the cluster categories, the signal-to-background ratio was improved and the impact of delayed particles from previous bunches could be reduced. Comparisons performed to the primary bunch-by-bunch luminosity measurement of the ATLAS experiment, provided by the LUCID-2 Cherenkov detector, show a good agreement.ac
Four Timepix3 detectors were installed in the ATLAS experiment at different positions to study their capabilities to measure luminosity during pp-collisions at sqrt(13) TeV in 2018. While the detectors were operated independently of the ATLAS triggering and acquisition scheme, continuous (dead-time free) measurement together with an orbit clock trigger allowed for synchronization with the LHC. The detectors benefit from a fine segmentation, a pixel pitch of 55 µm, and a per-pixel time resolution of 1.6 ns allowing for a high-quality track reconstruction and particle identification. One of the 500 µm thick silicon sensors was equipped with a 6LiF neutron converter, extending the particle identification capabilities. The installed system was used to study luminosity in different time frames: long term (run-by-run), short term (within a single run) and instantaneous (for each bunch crossing). For the long- and short-term luminosity, partly-independent algorithms: cluster and thermal neutron counting are proposed. A comprehensive analysis of the signal from induced radioactivity and its consecutive removal is presented together with a study demonstrating that the activation-corrected Timepix3 luminosity measurement provides good linearity with respect to the pile-up parameter. For measurement of the instantaneous luminosity, a cluster classification scheme was employed to decompose the measured response to the colliding bunch signal. Selecting a subset of the cluster categories, the signal-to-background ratio was improved and the impact of delayed particles from previous bunches could be reduced. Comparisons performed to the primary bunch-by-bunch luminosity measurement of the ATLAS experiment, provided by the LUCID-2 Cherenkov detector, show a good agreement.ac