DARWIN: towards the ultimate dark matter detector

J. Aalbers; F. Agostini; M. Alfonsi; F.D. Amaro; C. Amsler; E. Aprile; L. Arazi; F. Arneodo; P. Barrow; L. Baudis; M.L. Benabderrahmane; T. Berger; B. Beskers; A. Breskin; P.A. Breur; A. Brown; E. Brown; S. Bruenner; G. Bruno; R. Budnik; L. Bütikofer; J. Calvén; J.M.R. Cardoso; D. Cichon; D. Coderre; A.P. Colijn; J. Conrad; J.P. Cussonneau; M.P. Decowski; S. Diglio; G. Drexlin; E. Duchovni; E. Erdal; G. Eurin; A. Ferella; A. Fieguth; W. Fulgione; A. Gallo Rosso; P. Di Gangi; A. Di Giovanni; M. Galloway; M. Garbini; C. Geis; F. Glueck; L. Grandi; Z. Greene; C. Grignon; C. Hasterok; V. Hannen; E. Hogenbirk; J. Howlett; D. Hilk; C. Hils; A. James; B. Kaminsky; S. Kazama; B. Kilminster; A. Kish; L.M. Krauss; H. Landsman; R.F. Lang; Q. Lin; F.L. Linde; S. Lindemann; M. Lindner; J.A.M. Lopes; T. Marrodán Undagoitia; J. Masbou; F.V. Massoli; D. Mayani; M. Messina; K. Micheneau; A. Molinario; K.D. Morå; E. Morteau; M. Murra; J. Naganoma; J.L. Newstead; K. Ni; U. Oberlack; P. Pakarha; B. Pelssers; P. de Perio; R. Persiani; F. Piastra; M.C. Piro; G. Plante; L. Rauch; S. Reichard; A. Rizzo; N. Rupp; J.M.F. Dos Santos; G. Sartorelli; M. Scheibelhut; S. Schindler; M. Schumann; J. Schreiner; L. Scotto Lavina; M. Selvi; P. Shagin; M.C. Silva; H. Simgen; P. Sissol; M. von Sivers; D. Thers; J. Thurn; A. Tiseni; R. Trotta; C.D. Tunnell; K. Valerius; M.A. Vargas; H. Wang; Y. Wei; C. Weinheimer; T. Wester; J. Wulf; Y. Zhang; T. Zhu; K. Zuber

doi:10.1088/1475-7516/2016/11/017

Journal of Cosmology and Astroparticle Physics

DARWIN: towards the ultimate dark matter detector

J. Aalbers¹, F. Agostini^2,14, M. Alfonsi³, F.D. Amaro¹⁸, C. Amsler⁴, E. Aprile⁵, L. Arazi⁶, F. Arneodo⁷, P. Barrow⁸, L. Baudis⁸, M.L. Benabderrahmane⁷, T. Berger⁹, B. Beskers³, A. Breskin⁶, P.A. Breur¹, A. Brown¹, E. Brown⁹, S. Bruenner¹⁰, G. Bruno¹⁴, R. Budnik⁶, L. Bütikofer⁴, J. Calvén¹¹, J.M.R. Cardoso¹⁸, D. Cichon¹⁰, D. Coderre⁴, A.P. Colijn¹, J. Conrad¹¹, J.P. Cussonneau¹², M.P. Decowski¹, S. Diglio¹², G. Drexlin¹³, E. Duchovni⁶, E. Erdal⁶, G. Eurin¹⁰, A. Ferella¹¹, A. Fieguth²³, W. Fulgione¹⁴, A. Gallo Rosso¹⁴, P. Di Gangi², A. Di Giovanni⁷, M. Galloway⁸, M. Garbini², C. Geis³, F. Glueck¹³, L. Grandi¹⁵, Z. Greene⁵, C. Grignon³, C. Hasterok¹⁰, V. Hannen²³, E. Hogenbirk¹, J. Howlett⁵, D. Hilk¹³, C. Hils³, A. James⁸, B. Kaminsky⁴, S. Kazama⁸, B. Kilminster⁸, A. Kish⁸, L.M. Krauss¹⁶, H. Landsman⁶, R.F. Lang¹⁷, Q. Lin⁵, F.L. Linde¹, S. Lindemann¹⁰, M. Lindner¹⁰, J.A.M. Lopes¹⁸, T. Marrodán Undagoitia¹⁰, J. Masbou¹², F.V. Massoli², D. Mayani⁸, M. Messina⁵, K. Micheneau¹², A. Molinario¹⁴, K.D. Morå¹¹, E. Morteau¹², M. Murra²³, J. Naganoma²⁰, J.L. Newstead¹⁶, K. Ni¹⁹, U. Oberlack³, P. Pakarha⁸, B. Pelssers¹¹, P. de Perio⁵, R. Persiani¹², F. Piastra⁸, M.C. Piro⁹, G. Plante⁵, L. Rauch¹⁰, S. Reichard¹⁷, A. Rizzo⁵, N. Rupp¹⁰, J.M.F. Dos Santos¹⁸, G. Sartorelli², M. Scheibelhut³, S. Schindler³, M. Schumann^4,25, J. Schreiner¹⁰, L. Scotto Lavina¹², M. Selvi², P. Shagin²⁰, M.C. Silva¹⁸, H. Simgen¹⁰, P. Sissol³, M. von Sivers⁴, D. Thers¹², J. Thurn²⁴, A. Tiseni¹, R. Trotta²¹, C.D. Tunnell¹, K. Valerius¹³, M.A. Vargas²³, H. Wang²², Y. Wei⁸, C. Weinheimer²³, T. Wester²⁴, J. Wulf⁸, Y. Zhang⁵, T. Zhu⁵ and K. Zuber²⁴

Published 8 November 2016 • © 2016 IOP Publishing Ltd and Sissa Medialab srl
Journal of Cosmology and Astroparticle Physics, Volume 2016, November 2016 Citation J. Aalbers et al JCAP11(2016)017 DOI 10.1088/1475-7516/2016/11/017

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¹ Nikhef and the University of Amsterdam, Amsterdam, Netherlands

² Department of Physics and Astrophysics, University of Bologna and INFN-Bologna, Bologna, Italy

³ Institut für Physik & Exzellenzcluster PRISMA, Johannes Gutenberg-Universität Mainz, Mainz, Germany

⁴ Albert Einstein Center for Fundamental Physics, Universität Bern, Bern, Switzerland

⁵ Physics Department, Columbia University, New York, NY, U.S.A.

⁶ Department of Particle Physics and Astrophysics, Weizmann Institute of Science, Rehovot, Israel

⁷ New York University Abu Dhabi, United Arab Emirates

⁸ Physik-Institut, Universität Zürich, Zürich, Switzerland

⁹ Department of Physics, Applied Physics and Astronomy, Rensselaer Polytechnic Institute, Troy, NY, U.S.A.

¹⁰ Max-Planck-Institut für Kernphysik, Heidelberg, Germany

¹¹ Department of Physics, Stockholm University, Stockholm, Sweden

¹² Subatech, Ecole des Mines de Nantes, CNRS/In2p3, Université de Nantes, Nantes, France

¹³ Institut für Experimentelle Kernphysik, Karlsruhe Institute of Technology (KIT), Karlsruhe, Germany

¹⁴ INFN-Laboratori Nazionali del Gran Sasso and Gran Sasso Science Institute, L'Aquila, Italy

¹⁵ Kavli Institute, Enrico Fermi Institute and Dept. of Physics, University of Chicago, Chicago, IL, U.S.A.

¹⁶ Physics Department, Arizona State University, Tempe, AZ, U.S.A.

¹⁷ Department of Physics and Astronomy, Purdue University, West Lafayette, IN, U.S.A.

¹⁸ Department of Physics, University of Coimbra, Coimbra, Portugal

¹⁹ Department of Physics, University of California, San Diego, CA, U.S.A.

²⁰ Department of Physics and Astronomy, Rice University, Houston, TX, U.S.A.

²¹ Astrophysics Group & Data Science Institute, Imperial College London, U.K.

²² Physics & Astronomy Department, University of California, Los Angeles, CA, U.S.A.

²³ Institut für Kernphysik, Westfälische Wilhelms-Universität Münster, Münster, Germany

²⁴ Institute for Nuclear and Particle Physics, TU Dresden, Dresden, Germany

²⁵ Physikalisches Institut, Albert-Ludwigs-Universität Freiburg, Freiburg, Germany

Dates

Received 23 June 2016
Accepted 18 October 2016
Published 8 November 2016

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Abstract

DARk matter WImp search with liquid xenoN (DARWIN) will be an experiment for the direct detection of dark matter using a multi-ton liquid xenon time projection chamber at its core. Its primary goal will be to explore the experimentally accessible parameter space for Weakly Interacting Massive Particles (WIMPs) in a wide mass-range, until neutrino interactions with the target become an irreducible background. The prompt scintillation light and the charge signals induced by particle interactions in the xenon will be observed by VUV sensitive, ultra-low background photosensors. Besides its excellent sensitivity to WIMPs above a mass of 5 GeV/c², such a detector with its large mass, low-energy threshold and ultra-low background level will also be sensitive to other rare interactions. It will search for solar axions, galactic axion-like particles and the neutrinoless double-beta decay of ¹³⁶Xe, as well as measure the low-energy solar neutrino flux with < 1% precision, observe coherent neutrino-nucleus interactions, and detect galactic supernovae. We present the concept of the DARWIN detector and discuss its physics reach, the main sources of backgrounds and the ongoing detector design and R&D efforts.

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