Abstract
Electron and photon triggers covering transverse energies from 5 GeV to several TeV are essential for the ATLAS experiment to record signals for a wide variety of physics: from Standard Model processes to searches for new phenomena in both proton–proton and heavy-ion collisions. To cope with a fourfold increase of peak LHC luminosity from 2015 to 2018 (Run 2), to 2.1 × 1034 cm-2s-1, and a similar increase in the number of interactions per beam-crossing to about 60, trigger algorithms and selections were optimised to control the rates while retaining a high efficiency for physics analyses. For proton–proton collisions, the single-electron trigger efficiency relative to a single-electron offline selection is at least 75% for an offline electron of 31 GeV, and rises to 96% at 60 GeV; the trigger efficiency of a 25 GeV leg of the primary diphoton trigger relative to a tight offline photon selection is more than 96% for an offline photon of 30 GeV. For heavy-ion collisions, the primary electron and photon trigger efficiencies relative to the corresponding standard offline selections are at least 84% and 95%, respectively, at 5 GeV above the corresponding trigger threshold.
| Original language | English |
|---|---|
| Article number | 47 |
| Pages (from-to) | 1-41 |
| Number of pages | 41 |
| Journal | European Physical Journal C |
| Volume | 80 |
| Issue number | 1 |
| DOIs | |
| Publication status | Published - Jan 2020 |
| Externally published | Yes |
Bibliographical note
Copyright the Author(s) 2020. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.Cite this
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In: European Physical Journal C, Vol. 80, No. 1, 47, 01.2020, p. 1-41.
Research output: Contribution to journal › Article › peer-review
TY - JOUR
T1 - Performance of electron and photon triggers in ATLAS during LHC Run 2
AU - ATLAS Collaboration
AU - Aad, G.
AU - Abbott, B.
AU - Abbott, D. C.
AU - Abud, A. Abed
AU - Abeling, K.
AU - Abhayasinghe, D. K.
AU - Abidi, S. H.
AU - AbouZeid, O. S.
AU - Abraham, N. L.
AU - Abramowicz, H.
AU - Abreu, H.
AU - Abulaiti, Y.
AU - Acharya, B. S.
AU - Achkar, B.
AU - Adachi, S.
AU - Adam, L.
AU - Bourdarios, C. Adam
AU - Adamczyk, L.
AU - Adamek, L.
AU - Adelman, J.
AU - Adersberger, M.
AU - Adiguzel, A.
AU - Adorni, S.
AU - Adye, T.
AU - Affolder, A. A.
AU - Afik, Y.
AU - Agapopoulou, C.
AU - Agaras, M. N.
AU - Aggarwal, A.
AU - Agheorghiesei, C.
AU - Aguilar-Saavedra, J. A.
AU - Ahmadov, F.
AU - Ahmed, W. S.
AU - Ai, X.
AU - Aielli, G.
AU - Akatsuka, S.
AU - Åkesson, T. P.A.
AU - Akilli, E.
AU - Akimov, A. V.
AU - Khoury, K. Al
AU - Alberghi, G. L.
AU - Albert, J.
AU - Verzini, M. J.Alconada
AU - Alderweireldt, S.
AU - Aleksa, M.
AU - Aleksandrov, I. N.
AU - Alexa, C.
AU - Alexopoulos, T.
AU - Alfonsi, A.
AU - Alfonsi, F.
AU - Alhroob, M.
AU - Ali, B.
AU - Aliev, M.
AU - Alimonti, G.
AU - Alkire, S. P.
AU - Allaire, C.
AU - Allbrooke, B. M.M.
AU - Allen, B. W.
AU - Allport, P. P.
AU - Aloisio, A.
AU - Alonso, A.
AU - Alonso, F.
AU - Alpigiani, C.
AU - Alshehri, A. A.
AU - Estevez, M. Alvarez
AU - Piqueras, D. Álvarez
AU - Alviggi, M. G.
AU - Coutinho, Y. Amaral
AU - Ambler, A.
AU - Ambroz, L.
AU - Amelung, C.
AU - Amidei, D.
AU - Santos, S. P.Amor Dos
AU - Amoroso, S.
AU - Amrouche, C. S.
AU - An, F.
AU - Anastopoulos, C.
AU - Andari, N.
AU - Andeen, T.
AU - Anders, C. F.
AU - Anders, J. K.
AU - Andreazza, A.
AU - Andrei, V.
AU - Anelli, C. R.
AU - Angelidakis, S.
AU - Angerami, A.
AU - Anisenkov, A. V.
AU - Annovi, A.
AU - Antel, C.
AU - Anthony, M. T.
AU - Antipov, E.
AU - Antonelli, M.
AU - Antrim, D. J.A.
AU - Anulli, F.
AU - Aoki, M.
AU - Pozo, J. A.Aparisi
AU - Bella, L. Aperio
AU - Araque, J. P.
AU - Ferraz, V. Araujo
AU - Pereira, R. Araujo
AU - Arcangeletti, C.
AU - Arce, A. T.H.
AU - Arduh, F. A.
AU - Arguin, J. F.
AU - Argyropoulos, S.
AU - Arling, J. H.
AU - Armbruster, A. J.
AU - Armstrong, A.
AU - Arnaez, O.
AU - Arnold, H.
AU - Tame, Z. P.Arrubarrena
AU - Artoni, G.
AU - Artz, S.
AU - Asai, S.
AU - Asbah, N.
AU - Asimakopoulou, E. M.
AU - Asquith, L.
AU - Assahsah, J.
AU - Assamagan, K.
AU - Astalos, R.
AU - Atkin, R. J.
AU - Atkinson, M.
AU - Atlay, N. B.
AU - Atmani, H.
AU - Augsten, K.
AU - Avolio, G.
AU - Avramidou, R.
AU - Ayoub, M. K.
AU - Azoulay, A. M.
AU - Azuelos, G.
AU - Bachacou, H.
AU - Bachas, K.
AU - Backes, M.
AU - Backman, F.
AU - Bagnaia, P.
AU - Bahmani, M.
AU - Bahrasemani, H.
AU - Bailey, A. J.
AU - Bailey, V. R.
AU - Baines, J. T.
AU - Bajic, M.
AU - Bakalis, C.
AU - Baker, O. K.
AU - Bakker, P. J.
AU - Gupta, D. Bakshi
AU - Balaji, S.
AU - Baldin, E. M.
AU - Balek, P.
AU - Balli, F.
AU - Balunas, W. K.
AU - Balz, J.
AU - Banas, E.
AU - Bandyopadhyay, A.
AU - Banerjee, Sw
AU - Bannoura, A. A.E.
AU - Barak, L.
AU - Barbe, W. M.
AU - Barberio, E. L.
AU - Barberis, D.
AU - Barbero, M.
AU - Barbour, G.
AU - Barillari, T.
AU - Barisits, M. S.
AU - Barkeloo, J.
AU - Barklow, T.
AU - Barnea, R.
AU - Barnes, S. L.
AU - Barnett, B. M.
AU - Barnett, R. M.
AU - Barnovska-Blenessy, Z.
AU - Baroncelli, A.
AU - Barone, G.
AU - Barr, A. J.
AU - Navarro, L. Barranco
AU - Barreiro, F.
AU - da Costa, J. Barreiro Guimarães
AU - Barsov, S.
AU - Bartoldus, R.
AU - Bartolini, G.
AU - Barton, A. E.
AU - Bartos, P.
AU - Basalaev, A.
AU - Basan, A.
AU - Bassalat, A.
AU - Basso, M. J.
AU - Bates, R. L.
AU - Batlamous, S.
AU - Batley, J. R.
AU - Batool, B.
AU - Battaglia, M.
AU - Bauce, M.
AU - Bauer, F.
AU - Bauer, K. T.
AU - Bawa, H. S.
AU - Beacham, J. B.
AU - Beau, T.
AU - Beauchemin, P. H.
AU - Becherer, F.
AU - Bechtle, P.
AU - Beck, H. C.
AU - Beck, H. P.
AU - Becker, K.
AU - Becker, M.
AU - Becot, C.
AU - Beddall, A. J.
AU - Beddall, A. J.
AU - Bednyakov, V. A.
AU - Bedognetti, M.
AU - Bee, C. P.
AU - Beermann, T. A.
AU - Begalli, M.
AU - Begel, M.
AU - Behera, A.
AU - Behr, J. K.
AU - Beisiegel, F.
AU - Bell, A. S.
AU - Bella, G.
AU - Bellagamba, L.
AU - Bellerive, A.
AU - Bellos, P.
AU - Beloborodov, K.
AU - Belotskiy, K.
AU - Belyaev, N. L.
AU - Benchekroun, D.
AU - Benekos, N.
AU - Benhammou, Y.
AU - Benjamin, D. P.
AU - Benoit, M.
AU - Bensinger, J. R.
AU - Bentvelsen, S.
AU - Beresford, L.
AU - Beretta, M.
AU - Berge, D.
AU - Kuutmann, E. Bergeaas
AU - Berger, N.
AU - Bergmann, B.
AU - Bergsten, L. J.
AU - Beringer, J.
AU - Berlendis, S.
AU - Bernardi, G.
AU - Bernius, C.
AU - Berry, T.
AU - Berta, P.
AU - Bertella, C.
AU - Bertram, I. A.
AU - Bylund, O. Bessidskaia
AU - Besson, N.
AU - Bethani, A.
AU - Bethke, S.
AU - Shojaii, J.
N1 - Copyright the Author(s) 2020. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.
PY - 2020/1
Y1 - 2020/1
N2 - Electron and photon triggers covering transverse energies from 5 GeV to several TeV are essential for the ATLAS experiment to record signals for a wide variety of physics: from Standard Model processes to searches for new phenomena in both proton–proton and heavy-ion collisions. To cope with a fourfold increase of peak LHC luminosity from 2015 to 2018 (Run 2), to 2.1 × 1034 cm-2s-1, and a similar increase in the number of interactions per beam-crossing to about 60, trigger algorithms and selections were optimised to control the rates while retaining a high efficiency for physics analyses. For proton–proton collisions, the single-electron trigger efficiency relative to a single-electron offline selection is at least 75% for an offline electron of 31 GeV, and rises to 96% at 60 GeV; the trigger efficiency of a 25 GeV leg of the primary diphoton trigger relative to a tight offline photon selection is more than 96% for an offline photon of 30 GeV. For heavy-ion collisions, the primary electron and photon trigger efficiencies relative to the corresponding standard offline selections are at least 84% and 95%, respectively, at 5 GeV above the corresponding trigger threshold.
AB - Electron and photon triggers covering transverse energies from 5 GeV to several TeV are essential for the ATLAS experiment to record signals for a wide variety of physics: from Standard Model processes to searches for new phenomena in both proton–proton and heavy-ion collisions. To cope with a fourfold increase of peak LHC luminosity from 2015 to 2018 (Run 2), to 2.1 × 1034 cm-2s-1, and a similar increase in the number of interactions per beam-crossing to about 60, trigger algorithms and selections were optimised to control the rates while retaining a high efficiency for physics analyses. For proton–proton collisions, the single-electron trigger efficiency relative to a single-electron offline selection is at least 75% for an offline electron of 31 GeV, and rises to 96% at 60 GeV; the trigger efficiency of a 25 GeV leg of the primary diphoton trigger relative to a tight offline photon selection is more than 96% for an offline photon of 30 GeV. For heavy-ion collisions, the primary electron and photon trigger efficiencies relative to the corresponding standard offline selections are at least 84% and 95%, respectively, at 5 GeV above the corresponding trigger threshold.
UR - http://www.scopus.com/inward/record.url?scp=85078123210&partnerID=8YFLogxK
U2 - 10.1140/epjc/s10052-019-7500-2
DO - 10.1140/epjc/s10052-019-7500-2
M3 - Article
AN - SCOPUS:85078123210
SN - 1434-6052
VL - 80
SP - 1
EP - 41
JO - European Physical Journal C
JF - European Physical Journal C
IS - 1
M1 - 47
ER -