LUX-ZEPLIN

Low temperature scintillation properties of ga 2 o 3

Journal of Physical Studies Ivan Franko National University of Lviv 24:2 (2020)

Authors:

VB Mykhaylyk, H Kraus, V Kapustianyk, M Rudko, V Kolomiets

Projected sensitivity of the LUX-ZEPLIN experiment to the $0\nu\beta\beta$ decay of $^{136}$Xe

(2019)

Authors:

DS Akerib, CW Akerlof, A Alqahtani, SK Alsum, TJ Anderson, N Angelides, HM Araújo, JE Armstrong, M Arthurs, X Bai, J Balajthy, S Balashov, J Bang, A Baxter, J Bensinger, EP Bernard, A Bernstein, A Bhatti, A Biekert, TP Biesiadzinski, HJ Birch, KE Boast, B Boxer, P Brás, JH Buckley, VV Bugaev, S Burdin, JK Busenitz, R Cabrita, C Carels, DL Carlsmith, MC Carmona Benitez, M Cascella, C Chan, NI Chott, A Cole, A Cottle, JE Cutter, CE Dahl, L de Viveiros, JEY Dobson, E Druszkiewicz, TK Edberg, SR Eriksen, A Fan, S Fiorucci, H Flaecher, ED Fraser, T Fruth, RJ Gaitskell, J Genovesi, C Ghag, E Gibson, MGD Gilchriese, S Gokhale, MGD van der Grinten, CR Hall, A Harrison, SJ Haselschwardt, SA Hertel, J YK Hor, M Horn, DQ Huang, CM Ignarra, O Jahangir, W Ji, J Johnson, AC Kaboth, AC Kamaha, K Kamdin, K Kazkaz, D Khaitan, A Khazov, I Khurana, CD Kocher, L Korley, EV Korolkova, J Kras, H Kraus, S Kravitz, L Kreczko, B Krikler, VA Kudryavtsev, EA Leason, J Lee, DS Leonard, KT Lesko, C Levy, J Li, J Liao, FT Liao, J Lin, A Lindote, R Linehan, WH Lippincott, R Liu, X Liu, C Loniewski, MI Lopes, B López Paredes, W Lorenzon, S Luitz, JM Lyle, PA Majewski, A Manalaysay, L Manenti, RL Mannino, N Marangou, MF Marzioni, DN McKinsey, J McLaughlin, Y Meng, EH Miller, E Mizrachi, A Monte, ME Monzani, JA Morad, E Morrison, BJ Mount, A St J Murphy, D Naim, A Naylor, C Nedlik, C Nehrkorn, HN Nelson, F Neves, JA Nikoleyczik, A Nilima, K O'Sullivan, I Olcina, KC Oliver-Mallory, S Pal, KJ Palladino, J Palmer, N Parveen, EK Pease, B Penning, G Pereira, K Pushkin, J Reichenbacher, CA Rhyne, Q Riffard, GRC Rischbieter, R Rosero, P Rossiter, G Rutherford, D Santone, ABMR Sazzad, RW Schnee, M Schubnell, D Seymour, S Shaw, TA Shutt, JJ Silk, C Silva, R Smith, M Solmaz, VN Solovov, P Sorensen, I Stancu, A Stevens, K Stifter, TJ Sumner, N Swanson, M Szydagis, M Tan, WC Taylor, R Taylor, DJ Temples, PA Terman, DR Tiedt, M Timalsina, A Tomás, M Tripathi, DR Tronstad, W Turner, L Tvrznikova, U Utku, A Vacheret, A Vaitkus, JJ Wang, W Wang, JR Watson, RC Webb, RG White, TJ Whitis, FLH Wolfs, D Woodward, X Xiang, J Xu, M Yeh, P Zarzhitsky

Erratum to: Geant4-based electromagnetic background model for the CRESST dark matter experiment

European Physical Journal C Springer Nature 79:12 (2019) 987

Authors:

AH Abdelhameed, G Angloher, P Bauer, A Bento, E Bertoldo, R Breier, C Bucci, L Canonica, A D’Addabbo, S Di Lorenzo, A Erb, FV Feilitzsch, N Ferreiro Iachellini, S Fichtinger, A Fuss, P Gorla, D Hauff, M Jes̆kovský, J Jochum, J Kaizer, A Kinast, H Kluck, H Kraus, A Langenkämper, M Mancuso, V Mokina, E Mondragón, M Olmi, T Ortmann, C Pagliarone, V Palus̆ová, L Pattavina, F Petricca, W Potzel, P Povinec, F Pröbst, F Reindl, J Rothe, K Schäffner, J Schieck, V Schipperges, D Schmiedmayer, S Schönert, C Schwertner, M Stahlberg, L Stodolsky, C Strandhagen, R Strauss, C Türkoğlu, I Usherov, M Willers, V Zema, J Zeman

First results from the CRESST-III low-mass dark matter program

Physical Review D American Physical Society 100:10-15 (2019) 102002

Authors:

AH Abdelhameed, G Angloher, P Bauer, A Bento, E Bertoldo, C Bucci, L Canonica, A D’Addabbo, X Defay, S Di Lorenzo, A Erb, FV Feilitzsch, S Fichtinger, N Ferreiro Ferreiro Iachellini, A Fuss, P Gorla, D Hauff, J Jochum, A Kinast, H Kluck, Hans Kraus, A Langenkämper, M Mancuso, V Mokina, E Mondragon

Abstract:

The CRESST experiment is a direct dark matter search which aims to measure interactions of potential dark matter particles in an Earth-bound detector. With the current stage, CRESST-III, we focus on a low energy threshold for increased sensitivity towards light dark matter particles. In this paper we describe the analysis of one detector operated in the first run of CRESST-III (05/2016–02/2018) achieving a nuclear recoil threshold of 30.1 eV. This result was obtained with a 23.6 g CaWO 4 crystal operated as a cryogenic scintillating calorimeter in the CRESST setup at the Laboratori Nazionali del Gran Sasso (LNGS). Both the primary phonon (heat) signal and the simultaneously emitted scintillation light, which is absorbed in a separate silicon-on-sapphire light absorber, are measured with highly sensitive transition edge sensors operated at ∼ 15     mK . The unique combination of these sensors with the light element oxygen present in our target yields sensitivity to dark matter particle masses as low as 160     MeV / c 2 .

The LUX-ZEPLIN (LZ) experiment

Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment Elsevier 953 (2019) 163047

Authors:

DS Akerib, CW Akerlof, D Yu Akimov, Kathryn Boast, Amy Cottle, T Fruth, E Gibson, Hans Kraus, Andrew Stevens, Matthew Tan,

Abstract:

We describe the design and assembly of the LUX-ZEPLIN experiment, a direct detection search for cosmic WIMP dark matter particles. The centerpiece of the experiment is a large liquid xenon time projection chamber sensitive to low energy nuclear recoils. Rejection of backgrounds is enhanced by a Xe skin veto detector and by a liquid scintillator Outer Detector loaded with gadolinium for efficient neutron capture and tagging. LZ is located in the Davis Cavern at the 4850’ level of the Sanford Underground Research Facility in Lead, South Dakota, USA. We describe the major subsystems of the experiment and its key design features and requirements.