Performance of a full scale prototype detector at the BR2 reactor for the SoLid experiment

Research output: Contribution to journalArticlepeer-review


  • Yamiel Abreu
  • Y. Amhis
  • Lukas Arnold
  • G. Ban
  • Wim Beaumont
  • Mathieu Bongrand
  • Delphine Boursette
  • B.C. Castle
  • Keith Clark
  • David Cussans
  • Albert De Roeck
  • J. D'Hondt
  • D. Durand
  • M. Fallot
  • L. Giot
  • Benoit Guillon
  • Sakari Ihantola
  • X. Janssen
  • Leonidas Kalousis
  • Mathieu Labare
  • Gregory Lehaut
  • Luis Manzanillas
  • Ianthe Michiels
  • Dave Newbold
  • Jaewon Park
  • Valentin Pestel
  • K. Petridis
  • Ibrahin Pinera
  • G. Pommery
  • G. Pronost
  • J. Rademacker
  • Dirk Ryckbosch
  • Nick Ryder
  • Daniel Saunders
  • M.-H. Schune
  • Laurent Simard
  • Antonin Vacheret
  • Petra Van Mulders
  • Nick Van Remortel
  • Nick Van Remortel
  • Simon Vercaemer
  • Verstraeten Maja
  • Alfons Weber
  • Frederic Yermia

Institutes & Expert groups

  • University Paris-Sud
  • LPC - Laboratoire de Physique Corpusculaire de Caen
  • UA - Universiteit Antwerpen
  • University of Bristol
  • University of Oxford
  • CERN - Conseil Européen pour la Recherche Nucléaire
  • VUB - Vrije Universiteit Brussel
  • SUBATECH - Co-operated by École des mines de Nantes/Université de Nantes
  • Imperial College London
  • UGent - Universiteit Gent
  • STFC - Science and Technology Facilities Council
  • Virginia Polytechnic Institute and State University

Documents & links


The SoLid collaboration has developed a new detector technology to detect electronanti-neutrinos at close proximity to the Belgian BR2 reactor at surface level. A 288 kg prototype detector was deployed in 2015 and collected data during the operational period of the reactor and during reactor shut-down. Dedicated calibration campaigns were also performed with gamma and neutron sources. This paper describes the construction of the prototype detector with a high control on its proton content and the stability of its operation over a period of several months after deployment at the BR2 reactor site. All detector cells provide sufficient light yields to achieve a target energy resolution of better than 20%/sqrt(E[MeV]). The capability of the detector to track muons is exploited to equalize the light response of a large number of channels to a precision of 3% and to demonstrate the stability of the energy scale over time. Particle identification based on pulse-shape discrimination is demonstrated with calibration sources. Despite a lower neutron detection efficiency due to triggering constraints, the main backgrounds at the reactor site were determined and taken into account in the shielding strategy for the main experiment. The results obtained with this prototype proved essential in the design optimization of the final detector.


Original languageEnglish
Article numberP05005
Pages (from-to)1-29
Number of pages29
JournalJournal of Instrumentation
Issue numberP05005
Publication statusPublished - 3 May 2018


  • Large detector systems for particle and astroparticle physics, Neutrino detectors

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