Hans Kraus

Ultra-fast low temperature scintillation and X-ray luminescence of CsPbCl3 crystals

Journal of Materials Chemistry C Royal Society of Chemistry 11 (2022) 656-665

Authors:

Vb Mykhaylyk, M Rudko, H Kraus, V Kapustianyk, V Kolomiets, N Vitoratou, Y Chornodolskyy, As Voloshinovskii, L Vasylechko

Abstract:

Halide perovskites recently emerged as promising materials for the detection of ionising radiation. Single crystals of halide perovskites exhibit very fast and bright scintillation when cooled and may outperform the best modern scintillators at temperatures below 100 K. In this work we report on low-temperature scintillation properties of CsPbCl₃ single crystals, grown using the Bridgeman method. The temperature dependences of the luminescence and decay kinetics were studied using X-ray excitation. At low temperatures, the crystal exhibits an intense narrow-band emission at about 420 nm with very fast decay kinetics. This emission, of which a characteristic feature is the strong thermal quenching, is attributed to the radiative decays of bound and trapped excitons. The fast, middle, and slow decay time constants obtained from a fit of a sum of exponential functions to the decay curve at 10 K are 0.1, 1 and 11 ns, respectively. The scintillation light yield of CsPbCl₃ at 7 K measured at excitation with α-particles from an ²⁴¹Am source is estimated to be 140 ± 15% of a reference LYSO-Ce crystal and 19000 ± 2000 ph per MeV under 14 keV X-ray excitation at 10 K. It is concluded that owing to a reduced amplitude of the slow decay component, CsPbCl₃ exhibits an ultra-fast scintillation response that is superior to that of other halide perovskites. The combination of sub-nanosecond response time and the encouraging light yield has the potential of establishing this material as first choice for scintillation applications that rely on prompt detector response at cryogenic temperatures.

Improving the Quality of CaWO4 Target Crystals for CRESST

Journal of Low Temperature Physics Springer Nature 209:5-6 (2022) 1128-1134

Authors:

A Kinast, G Angloher, G Benato, A Bento, A Bertolini, R Breier, C Bucci, L Canonica, A D’Addabbo, S Di Lorenzo, L Einfalt, A Erb, FV Feilitzsch, N Ferreiro Iachellini, S Fichtinger, D Fuchs, A Fuss, A Garai, V-M Ghete, P Gorla, S Gupta, F Hamilton, D Hauff, M Ješkovský, J Jochum, M Kaznacheeva, H Kluck, H Kraus, A Langenkämper, M Mancuso, L Marini, V Mokina, A Nilima, M Olmi, T Ortmann, C Pagliarone, V Palušová, L Pattavina, F Petricca, W Potzel, P Povinec, F Pröbst, F Pucci, F Reindl, J Rothe, K Schäffner, J Schieck, D Schmiedmayer, S Schönert, C Schwertner, M Stahlberg, L Stodolsky, C Strandhagen, R Strauss, I Usherov, F Wagner, M Willers, V Zema

Background Determination for the LUX-ZEPLIN (LZ) Dark Matter Experiment

(2022)

Authors:

J Aalbers, DS Akerib, AK Al Musalhi, F Alder, SK Alsum, CS Amarasinghe, A Ames, TJ Anderson, N Angelides, HM Araújo, JE Armstrong, M Arthurs, A Baker, J Bang, JW Bargemann, A Baxter, K Beattie, P Beltrame, EP Bernard, A Bhatti, A Biekert, TP Biesiadzinski, HJ Birch, GM Blockinger, B Boxer, CAJ Brew, P Brás, S Burdin, M Buuck, R Cabrita, MC Carmona-Benitez, C Chan, A Chawla, H Chen, APS Chiang, NI Chott, MV Converse, A Cottle, G Cox, O Creaner, CE Dahl, A David, S Dey, L de Viveiros, C Ding, JEY Dobson, E Druszkiewicz, SR Eriksen, A Fan, NM Fearon, S Fiorucci, H Flaecher, ED Fraser, T Fruth, RJ Gaitskell, J Genovesi, C Ghag, R Gibbons, MGD Gilchriese, S Gokhale, J Green, MGD van der Grinten, CB Gwilliam, CR Hall, S Han, E Hartigan-O'Connor, SJ Haselschwardt, SA Hertel, G Heuermann, M Horn, DQ Huang, D Hunt, CM Ignarra, RG Jacobsen, O Jahangir, RS James, J Johnson, AC Kaboth, AC Kamaha, D Khaitan, I Khurana, R Kirk, D Kodroff, L Korley, EV Korolkova, H Kraus, S Kravitz, L Kreczko, B Krikler, VA Kudryavtsev, EA Leason, J Lee, DS Leonard, KT Lesko, C Levy, J Lin, A Lindote, R Linehan, WH Lippincott, X Liu, MI Lopes, E Lopez Asamar, B López Paredes, W Lorenzon, C Lu, S Luitz, PA Majewski, A Manalaysay, RL Mannino, N Marangou, ME McCarthy, DN McKinsey, J McLaughlin, EH Miller, E Mizrachi, A Monte, ME Monzani, JD Morales Mendoza, E Morrison, BJ Mount, M Murdy, A St J Murphy, D Naim, A Naylor, C Nedlik, HN Nelson, F Neves, A Nguyen, JA Nikoleyczik, I Olcina, KC Oliver-Mallory, J Orpwood, KJ Palladino, J Palmer, N Parveen, SJ Patton, B Penning, G Pereira, E Perry, T Pershing, A Piepke, D Porzio, S Poudel, Y Qie, J Reichenbacher, CA Rhyne, Q Riffard, GRC Rischbieter, HS Riyat, R Rosero, P Rossiter, T Rushton, D Santone, ABMR Sazzad, RW Schnee, S Shaw, T Shutt, JJ Silk, C Silva, G Sinev, R Smith, M Solmaz, VN Solovov, P Sorensen, J Soria, I Stancu, A Stevens, K Stifter, B Suerfu, TJ Sumner, N Swanson, M Szydagis, R Taylor, WC Taylor, DJ Temples, PA Terman, DR Tiedt, M Timalsina, Z Tong, DR Tovey, J Tranter, M Trask, M Tripathi, DR Tronstad, W Turner, U Utku, AC Vaitkus, A Wang, JJ Wang, W Wang, Y Wang, JR Watson, RC Webb, TJ Whitis, M Williams, FLH Wolfs, S Woodford, D Woodward, CJ Wright, Q Xia, X Xiang, J Xu, M Yeh

Testing spin-dependent dark matter interactions with lithium aluminate targets in CRESST-III

Physical Review D American Physical Society 106:9 (2022) 92008

Authors:

G Angloher, S Banik, G Benato, A Bento, A Bertolini, R Breier, C Bucci, J Burkhart, L Canonica, A D'Addabbo, S Di Lorenzo, L Einfalt, A Erb, Fv Feilitzsch, N Ferreiro Iachellini, S Fichtinger, D Fuchs, A Fuss, A Garai, Vm Ghete, S Gerster, P Gorla, Pv Guillaumon, S Gupta, D Hauff, M Ješkovský, J Jochum, M Kaznacheeva, A Kinast, H Kluck, H Kraus, A Langenkämper, M Mancuso, L Marini, L Meyer, V Mokina, A Nilima, M Olmi, T Ortmann, C Pagliarone, L Pattavina, F Petricca, W Potzel, P Povinec, F Pröbst, F Pucci, F Reindl, J Rothe, K Schäffner, J Schieck

Abstract:

In the past decades, numerous experiments have emerged to unveil the nature of dark matter, one of the most discussed open questions in modern particle physics. Among them, the Cryogenic Rare Event Search with Superconducting Thermometers (CRESST) experiment, located at the Laboratori Nazionali del Gran Sasso, operates scintillating crystals as cryogenic phonon detectors. In this work, we present first results from the operation of two detector modules which both have 10.46 g LiAlO2 targets in CRESST-III. The lithium contents in the crystal are Li6, with an odd number of protons and neutrons, and Li7, with an odd number of protons. By considering both isotopes of lithium and Al27, we set the currently strongest cross section upper limits on spin-dependent interaction of dark matter with protons and neutrons for the mass region between 0.25 and 1.5 GeV/c2.

The MIGDAL experiment: Measuring a rare atomic process to aid the search for dark matter

(2022)

Authors:

HM Araújo, SN Balashov, JE Borg, FM Brunbauer, C Cazzaniga, CD Frost, F Garcia, AC Kaboth, M Kastriotou, I Katsioulas, A Khazov, H Kraus, VA Kudryavtsev, S Lilley, A Lindote, D Loomba, MI Lopes, E Lopez Asamar, P Luna Dapica, PA Majewski, T Marley, C McCabe, AF Mills, M Nakhostin, T Neep, F Neves, K Nikolopoulos, E Oliveri, L Ropelewski, E Tilly, VN Solovov, TJ Sumner, J Tarrant, R Turnley, MGD van der Grinten, R Veenhof