Reflectivity and PDE of VUV4 Hamamatsu SiPMs in liquid xenon

P. Nakarmi; I. Ostrovskiy; A.K. Soma; F. Retière; S. Al Kharusi; M. Alfaris; G. Anton; I.J. Arnquist; I. Badhrees; P.S. Barbeau; D. Beck; V. Belov; T. Bhatta; J. Blatchford; P.A. Breur; J.P. Brodsky; E. Brown; T. Brunner; S. Byrne Mamahit; E. Caden; G.F. Cao; L. Cao; C. Chambers; B. Chana; S.A. Charlebois; M. Chiu; B. Cleveland; M. Coon; A. Craycraft; J. Dalmasson; T. Daniels; L. Darroch; A. De St. Croix; A. Der Mesrobian-Kabakian; R. DeVoe; M.L. Di Vacri; J. Dilling; Y.Y. Ding; M.J. Dolinski; L. Doria; A. Dragone; J. Echevers; F. Edaltafar; M. Elbeltagi; L. Fabris; D. Fairbank; W. Fairbank; J. Farine; S. Ferrara; S. Feyzbakhsh; R. Fontaine; A. Fucarino; G. Gallina; P. Gautam; G. Giacomini; D. Goeldi; R. Gornea; G. Gratta; E.V. Hansen; M. Heffner; E.W. Hoppe; J. Hößl; A. House; M. Hughes; A. Iverson; A. Jamil; M.J. Jewell; X.S. Jiang; A. Karelin; L.J. Kaufman; T. Koffas; R. Krücken; A. Kuchenkov; K.S. Kumar; Y. Lan; A. Larson; K.G. Leach; B.G. Lenardo; D.S. Leonard; G. Li; S. Li; Z. Li; C. Licciardi; P. Lv; R. MacLellan; N. Massacret; T. McElroy; M. Medina-Peregrina; T. Michel; B. Mong; D.C. Moore; K. Murray; C.R. Natzke; R.J. Newby; Z. Ning; O. Njoya; F. Nolet; O. Nusair; K. Odgers; A. Odian; M. Oriunno; J.L. Orrell; G.S. Ortega; C.T. Overman; S. Parent; A. Piepke; A. Pocar; J.-F. Pratte; V. Radeka; E. Raguzin; S. Rescia; M. Richman; A. Robinson; T. Rossignol; P.C. Rowson; N. Roy; J. Runge; R. Saldanha; S. Sangiorgio; K. Skarpaas VIII; G. St-Hilaire; V. Stekhanov; T. Stiegler; X.L. Sun; M. Tarka; J. Todd; T.I. Totev; R. Tsang; T. Tsang; F. Vachon; V. Veeraraghavan; S. Viel; G. Visser; C. Vivo-Vilches; J.-L. Vuilleumier; M. Wagenpfeil; T. Wager; M. Walent; Q. Wang; M. Ward; J. Watkins; M. Weber; W. Wei; L.J. Wen; U. Wichoski; S.X. Wu; W.H. Wu; X. Wu; Q. Xia; H. Yang; L. Yang; O. Zeldovich; J. Zhao; Y. Zhou; T. Ziegler

doi:10.1088/1748-0221/15/01/P01019

Journal of Instrumentation

Reflectivity and PDE of VUV4 Hamamatsu SiPMs in liquid xenon

P. Nakarmi¹, I. Ostrovskiy¹, A.K. Soma¹, F. Retière², S. Al Kharusi³, M. Alfaris⁴, G. Anton⁵, I.J. Arnquist⁶, I. Badhrees⁷, P.S. Barbeau⁸, D. Beck⁹, V. Belov¹⁰, T. Bhatta¹¹, J. Blatchford⁴, P.A. Breur¹², J.P. Brodsky¹³, E. Brown¹⁴, T. Brunner^2,3, S. Byrne Mamahit², E. Caden¹⁵, G.F. Cao¹⁶, L. Cao¹⁷, C. Chambers³, B. Chana⁷, S.A. Charlebois¹⁸, M. Chiu¹⁹, B. Cleveland¹⁵, M. Coon⁹, A. Craycraft²⁰, J. Dalmasson²¹, T. Daniels²², L. Darroch³, A. De St. Croix^2,24, A. Der Mesrobian-Kabakian¹⁵, R. DeVoe²¹, M.L. Di Vacri⁶, J. Dilling^2,24, Y.Y. Ding¹⁶, M.J. Dolinski²⁵, L. Doria², A. Dragone¹², J. Echevers⁹, F. Edaltafar², M. Elbeltagi⁷, L. Fabris²⁶, D. Fairbank²⁰, W. Fairbank²⁰, J. Farine¹⁵, S. Ferrara⁶, S. Feyzbakhsh⁴, R. Fontaine¹⁸, A. Fucarino¹⁴, G. Gallina^2,24, P. Gautam²⁵, G. Giacomini¹⁹, D. Goeldi⁷, R. Gornea^2,7, G. Gratta²¹, E.V. Hansen²⁵, M. Heffner¹³, E.W. Hoppe⁶, J. Hößl⁵, A. House¹³, M. Hughes¹, A. Iverson²⁰, A. Jamil²⁷, M.J. Jewell²¹, X.S. Jiang¹⁶, A. Karelin¹⁰, L.J. Kaufman¹², T. Koffas⁷, R. Krücken^2,24, A. Kuchenkov¹⁰, K.S. Kumar⁴, Y. Lan^2,24, A. Larson¹¹, K.G. Leach²⁸, B.G. Lenardo²¹, D.S. Leonard²⁹, G. Li²¹, S. Li⁹, Z. Li²⁷, C. Licciardi¹⁵, P. Lv¹⁶, R. MacLellan¹¹, N. Massacret², T. McElroy³, M. Medina-Peregrina³, T. Michel⁵, B. Mong¹², D.C. Moore²⁷, K. Murray³, C.R. Natzke²⁸, R.J. Newby²⁶, Z. Ning¹⁶, O. Njoya³⁰, F. Nolet¹⁸, O. Nusair¹, K. Odgers¹⁴, A. Odian¹², M. Oriunno¹², J.L. Orrell⁶, G.S. Ortega⁶, C.T. Overman⁶, S. Parent¹⁸, A. Piepke¹, A. Pocar⁴, J.-F. Pratte¹⁸, V. Radeka¹⁹, E. Raguzin¹⁹, S. Rescia¹⁹, M. Richman²⁵, A. Robinson¹⁵, T. Rossignol¹⁸, P.C. Rowson¹², N. Roy¹⁸, J. Runge⁸, R. Saldanha⁶, S. Sangiorgio¹³, K. Skarpaas VIII¹², G. St-Hilaire¹⁸, V. Stekhanov¹⁰, T. Stiegler¹³, X.L. Sun¹⁶, M. Tarka⁴, J. Todd²⁰, T.I. Totev³, R. Tsang⁶, T. Tsang¹⁹, F. Vachon¹⁸, V. Veeraraghavan¹, S. Viel⁷, G. Visser²³, C. Vivo-Vilches⁷, J.-L. Vuilleumier³¹, M. Wagenpfeil⁵, T. Wager²⁰, M. Walent¹⁵, Q. Wang¹⁷, M. Ward², J. Watkins⁷, M. Weber²¹, W. Wei¹⁶, L.J. Wen¹⁶, U. Wichoski¹⁵, S.X. Wu²¹, W.H. Wu¹⁶, X. Wu¹⁷, Q. Xia²⁷, H. Yang¹⁷, L. Yang⁹, O. Zeldovich¹⁰, J. Zhao¹⁶, Y. Zhou¹⁷ and T. Ziegler⁵

Published 17 January 2020 • © 2020 IOP Publishing Ltd and Sissa Medialab
Journal of Instrumentation, Volume 15, January 2020 Citation P. Nakarmi et al 2020 JINST 15 P01019 DOI 10.1088/1748-0221/15/01/P01019

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¹ Department of Physics and Astronomy, University of Alabama, Tuscaloosa, AL 35487, U.S.A.

² TRIUMF, Vancouver, British Columbia V6T 2A3, Canada

³ Physics Department, McGill University, Montréal, Québec H3A 2T8, Canada

⁴ Amherst Center for Fundamental Interactions and Physics Department, University of Massachusetts, Amherst, MA 01003, U.S.A.

⁵ Erlangen Centre for Astroparticle Physics (ECAP), Friedrich-Alexander University Erlangen-Nürnberg, Erlangen 91058, Germany

⁶ Pacific Northwest National Laboratory, Richland, WA 99352, U.S.A.

⁷ Department of Physics, Carleton University, Ottawa, Ontario K1S 5B6, Canada

⁸ Department of Physics, Duke University, and Triangle Universities Nuclear Laboratory (TUNL), Durham, NC 27708, U.S.A.

⁹ Physics Department, University of Illinois, Urbana-Champaign, IL 61801, U.S.A.

¹⁰ Institute for Theoretical and Experimental Physics named by A. I. Alikhanov of National Research Center "Kurchatov Institute", Moscow 117218, Russia

¹¹ Department of Physics, University of South Dakota, Vermillion, SD 57069, U.S.A.

¹² SLAC National Accelerator Laboratory, Menlo Park, CA 94025, U.S.A.

¹³ Lawrence Livermore National Laboratory, Livermore, CA 94550, U.S.A.

¹⁴ Department of Physics, Applied Physics and Astronomy, Rensselaer Polytechnic Institute, Troy, NY 12180, U.S.A.

¹⁵ Department of Physics, Laurentian University, Sudbury, Ontario P3E 2C6 Canada

¹⁶ Institute of High Energy Physics, Chinese Academy of Sciences, Beijing 100049, China

¹⁷ Institute of Microelectronics, Chinese Academy of Sciences, Beijing 100029, China

¹⁸ Université de Sherbrooke, Sherbrooke, Québec J1K 2R1, Canada

¹⁹ Brookhaven National Laboratory, Upton, NY 11973, U.S.A.

²⁰ Physics Department, Colorado State University, Fort Collins, CO 80523, U.S.A.

²¹ Physics Department, Stanford University, Stanford, CA 94305, U.S.A.

²² Department of Physics and Physical Oceanography, University of North Carolina at Wilmington, Wilmington, NC 28403, U.S.A.

²³ Department of Physics and CEEM, Indiana University, Bloomington, IN 47405, U.S.A.

²⁴ Department of Physics and Astronomy, University of British Columbia, Vancouver, British Columbia V6T 1Z1, Canada

²⁵ Department of Physics, Drexel University, Philadelphia, PA 19104, U.S.A.

²⁶ Oak Ridge National Laboratory, Oak Ridge, TN 37831, U.S.A.

²⁷ Wright Laboratory, Department of Physics, Yale University, New Haven, CT 06511, U.S.A.

²⁸ Department of Physics, Colorado School of Mines, Golden, CO 80401, U.S.A.

²⁹ IBS Center for Underground Physics, Daejeon 34126, Korea

³⁰ Department of Physics and Astronomy, Stony Brook University, SUNY, Stony Brook, NY 11794, U.S.A.

³¹ LHEP, Albert Einstein Center, University of Bern, Bern CH-3012, Switzerland

Dates

Received 16 October 2019
Accepted 18 December 2019
Published 17 January 2020

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Abstract

Understanding reflective properties of materials and photodetection efficiency (PDE) of photodetectors is important for optimizing energy resolution and sensitivity of the next generation neutrinoless double beta decay, direct detection dark matter, and neutrino oscillation experiments that will use noble liquid gases, such as nEXO, DARWIN, DarkSide-20k, and DUNE . Little information is currently available about reflectivity and PDE in liquid noble gases, because such measurements are difficult to conduct in a cryogenic environment and at short enough wavelengths. Here we report a measurement of specular reflectivity and relative PDE of Hamamatsu VUV4 silicon photomultipliers (SiPMs) with 50 μm micro-cells conducted with xenon scintillation light (∼175 nm) in liquid xenon. The specular reflectivity at 15^o incidence of three samples of VUV4 SiPMs is found to be 30.4±1.4%, 28.6±1.3%, and 28.0±1.3%, respectively. The PDE at normal incidence differs by ±8% (standard deviation) among the three devices. The angular dependence of the reflectivity and PDE was also measured for one of the SiPMs. Both the reflectivity and PDE decrease as the angle of incidence increases. This is the first measurement of an angular dependence of PDE and reflectivity of a SiPM in liquid xenon.

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