Performance of the LHCb Vertex Locator

R Aaij; A Affolder; K Akiba; M Alexander; S Ali; R B Appleby; M Artuso; A Bates; A Bay; O Behrendt; J Benton; M van Beuzekom; P M Bjørnstad; G Bogdanova; S Borghi; A Borgia; T J V Bowcock; J van den Brand; H Brown; J Buytaert; O Callot; J Carroll; G Casse; P Collins; S De Capua; M Doets; S Donleavy; D Dossett; R Dumps; D Eckstein; L Eklund; C Farinelli; S Farry; M Ferro-Luzzi; R Frei; J Garofoli; M Gersabeck; T Gershon; A Gong; H Gong; H Gordon; G Haefeli; J Harrison; V Heijne; K Hennessy; W Hulsbergen; T Huse; D Hutchcroft; A Jaeger; P Jalocha; E Jans; M John; J Keaveney; T Ketel; M Korolev; M Kraan; T Laštovička; G Lafferty; T Latham; G Lefeuvre; A Leflat; M Liles; A van Lysebetten; G MacGregor; F Marinho; R McNulty; M Merkin; D Moran; R Mountain; I Mous; J Mylroie-Smith; M Needham; N Nikitin; A Noor; A Oblakowska-Mucha; A Papadelis; M Pappagallo; C Parkes; G D Patel; B Rakotomiaramanana; S Redford; M Reid; K Rinnert; E Rodrigues; A F Saavedra; M Schiller; O Schneider; T Shears; R Silva Coutinho; N A Smith; T Szumlak; C Thomas; J van Tilburg; M Tobin; J Velthuis; B Verlaat; S Viret; V Volkov; C Wallace; J Wang; A Webber; M Whitehead; E Zverev

doi:10.1088/1748-0221/9/09/P09007

Journal of Instrumentation

The following article is Open access

Performance of the LHCb Vertex Locator

R Aaij¹, A Affolder², K Akiba³, M Alexander⁴, S Ali¹, R B Appleby⁵, M Artuso⁶, A Bates⁴, A Bay⁷, O Behrendt⁸, J Benton⁹, M van Beuzekom¹, P M Bjørnstad⁵, G Bogdanova¹⁰, S Borghi⁵, A Borgia⁶, T J V Bowcock², J van den Brand¹, H Brown², J Buytaert⁸, O Callot¹¹, J Carroll², G Casse², P Collins⁸, S De Capua⁵, M Doets¹, S Donleavy², D Dossett¹², R Dumps⁸, D Eckstein¹³, L Eklund⁴, C Farinelli¹, S Farry², M Ferro-Luzzi⁸, R Frei⁷, J Garofoli⁶, M Gersabeck⁵, T Gershon¹², A Gong¹⁴, H Gong¹⁴, H Gordon⁸, G Haefeli⁷, J Harrison⁵, V Heijne¹, K Hennessy², W Hulsbergen¹, T Huse¹⁵, D Hutchcroft², A Jaeger¹⁶, P Jalocha¹⁷, E Jans¹, M John¹⁷, J Keaveney¹⁸, T Ketel¹, M Korolev¹⁰, M Kraan¹, T Laštovička¹⁹, G Lafferty⁵, T Latham¹², G Lefeuvre⁶, A Leflat¹⁰, M Liles², A van Lysebetten¹, G MacGregor⁵, F Marinho²⁰, R McNulty²¹, M Merkin¹⁰, D Moran²², R Mountain⁶, I Mous¹, J Mylroie-Smith², M Needham²³, N Nikitin¹⁰, A Noor², A Oblakowska-Mucha²⁴, A Papadelis¹, M Pappagallo⁴, C Parkes⁵, G D Patel², B Rakotomiaramanana⁷, S Redford⁸, M Reid¹², K Rinnert², E Rodrigues⁵, A F Saavedra²⁵, M Schiller¹, O Schneider⁷, T Shears², R Silva Coutinho¹², N A Smith², T Szumlak²⁴, C Thomas¹⁷, J van Tilburg¹, M Tobin⁷, J Velthuis⁹, B Verlaat¹, S Viret²⁶, V Volkov¹⁰, C Wallace¹², J Wang⁶, A Webber⁵, M Whitehead¹² and E Zverev¹⁰

Published 9 September 2014 • © CERN 2014 for the benefit of the LHCb collaboration.
Journal of Instrumentation, Volume 9, September 2014 Citation R Aaij et al 2014 JINST 9 P09007 DOI 10.1088/1748-0221/9/09/P09007

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¹ Nikhef National Institute for Subatomic Physics, Amsterdam, Netherlands

² Oliver Lodge Laboratory, University of Liverpool, Liverpool, United Kingdom

³ Universidade Federal do Rio de Janeiro (UFRJ), Rio de Janeiro, Brazil

⁴ School of Physics and Astronomy, University of Glasgow, Glasgow, United Kingdom

⁵ School of Physics and Astronomy, University of Manchester, Manchester, United Kingdom

⁶ Syracuse University, Syracuse, NY, United States

⁷ Ecole Polytechnique Fédérale de Lausanne (EPFL), Lausanne, Switzerland

⁸ European Organization for Nuclear Research (CERN), Geneva, Switzerland

⁹ H.H. Wills Physics Laboratory, University of Bristol, Bristol, United Kingdom

¹⁰ Institute of Nuclear Physics, Moscow State University (SINP MSU), Moscow, Russia

¹¹ LAL, Université Paris-Sud, CNRS/IN2P3, Orsay, France

¹² Department of Physics, University of Warwick, Coventry, United Kingdom

¹³ Deutsches Elektronen-Synchrotron, Hamburg, Germany

¹⁴ Center for High Energy Physics, Tsinghua University, Beijing, China

¹⁵ Department of Physics, University of Oslo, Oslo, Norway

¹⁶ Physikalisches Institut, Ruprecht-Karls-Universität Heidelberg, Heidelberg, Germany

¹⁷ Department of Physics, University of Oxford, Oxford, United Kingdom

¹⁸ Vrije Universiteit Brussel, Brussel, Belgium

¹⁹ Institute of Physics, Academy of Sciences of the Czech Republic, Prague, Czech Republic

²⁰ Universidade Federal do Rio de Janeiro, Campus UFRJ - Macaé, Rio de Janeiro, Brazil

²¹ School of Physics, University College Dublin, Dublin, Ireland

²² Universidad Autónoma de Madrid, Spain

²³ School of Physics and Astronomy, University of Edinburgh, Edinburgh, United Kingdom

²⁴ AGH - University of Science and Technology, Faculty of Physics and Applied Computer Science, Kraków, Poland

²⁵ School of Physics, University of Sydney, Sydney, Australia

²⁶ Université de Lyon, Université Claude Bernard Lyon 1, CNRS-IN2P3, Institut de Physique Nucléaire de Lyon, Villeurbanne, France

Dates

Received 30 May 2014
Accepted 14 July 2014
Published 9 September 2014

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Abstract

The Vertex Locator (VELO) is a silicon microstrip detector that surrounds the proton-proton interaction region in the LHCb experiment. The performance of the detector during the first years of its physics operation is reviewed. The system is operated in vacuum, uses a bi-phase CO₂ cooling system, and the sensors are moved to 7 mm from the LHC beam for physics data taking. The performance and stability of these characteristic features of the detector are described, and details of the material budget are given. The calibration of the timing and the data processing algorithms that are implemented in FPGAs are described. The system performance is fully characterised. The sensors have a signal to noise ratio of approximately 20 and a best hit resolution of 4 μm is achieved at the optimal track angle. The typical detector occupancy for minimum bias events in standard operating conditions in 2011 is around 0.5%, and the detector has less than 1% of faulty strips. The proximity of the detector to the beam means that the inner regions of the n⁺-on-n sensors have undergone space-charge sign inversion due to radiation damage. The VELO performance parameters that drive the experiment's physics sensitivity are also given. The track finding efficiency of the VELO is typically above 98% and the modules have been aligned to a precision of 1 μm for translations in the plane transverse to the beam. A primary vertex resolution of 13 μm in the transverse plane and 71 μm along the beam axis is achieved for vertices with 25 tracks. An impact parameter resolution of less than 35 μm is achieved for particles with transverse momentum greater than 1 GeV/c.

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Performance of the LHCb Vertex Locator

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