SiPM-matrix readout of two-phase argon detectors using electroluminescence in the visible and near infrared range

Aalseth, Craig E.; Abdelhakim, S.; Agnes, P.; Ajaj, Rahaf; Albuquerque, I. F. M.; Alexander, T.; Alici, A.; Alton, A.; Amaudruz, P.; Ameli, F.; Anstey, James; Antonioli, P.; Arba, M.; Arcelli, S.; Ardito, Raffaele; Arnquist, I. J.; Arpaïa, Pasquale; Asner, D. M.; Asunskis, A.; Ave, M.; Back, H. O.; Barbaryan, V.; Olmedo, A. Barrado; Batignani, G.; Bisogni, Maria Giuseppina; Bocci, V.; Bondar, A.; Bonfini, G.; Bonivento, W.; Borisova, E.; Bottino, B.; Boulay, M. G.; Bunker, R.; Bussino, S.; Buzulutskov, A.; Cadeddu, M.; Cadoni, Mariano; Caminata, A.; Canci, N.; Candela, A.; Cantini, C.; Caravati, M.; Cariello, M.; Carnesecchi, F.; Castellani, A.; Castello, Paolo; Cavalcante, P.; Cavazza, D.; Cavuoti, S.; Cebrián, S.; Ruiz, J. M. Cela; Celano, B.; Cereseto, R.; Chashin, S.; Cheng, W.; Chepurnov, A.; Cicalò, C.; Cifarelli, L.; Citterio, M.; Coccetti, F.; Cocco, V.; Colocci, M.; Vilda, E. Conde; Consiglio, L.; Cossio, F.; Covone, G.; Crivelli, P.; D’Antone, I.; D’Incecco, M.; Rolo, M.; Dadoun, O.; Daniel, M. K.; Davini, S.; Cecco, S. De; Deo, M. De; Falco, A. De; Gruttola, D. De; Guido, Giorgia De; Rosa, G. De; Dellacasa, G.; Demontis, Pierfranco; Pasquale, S. De; Derbin, A.; Devoto, A.; Eusanio, F. Di; Noto, L. Di; Pietro, G. Di; Stéfano, P. Di; Dionisi, C.; Dolganov, G.; Dordei, F.; Downing, M.; Edalatfar, F.; Empl, A.; Diaz, M. Fernandez; Filip, Claudiu; Fiorillo, G.; Fomenko, K.; Franceschi, A.; Franco, D.; Frolov, E.; Froudakis, George E.; Funicello, Nicola; Gabriele, F.; Gabrieli, Andrea; Galbiati, C.; Garbini, M.; Abia, P. García; Gascon, D.; Gendotti, A.; Ghiano, C.; Ghisi, Aldo; Giampa, P.; Giampaolo, R. A.; Giganti, C.; Giorgi, M. A.; Giovanetti, G. K.; Gligan, M. L.; Gorchakov, O.E.; Grab, M.; Diaz, R. Graciani; Grassi, M.; Grate, Jay W.; Grobov, A.; Gromov, M.; Guan, Mengyun; Guerra, Marcelo Braga Bueno; Guerzoni, M.; Gulino, M.; Haaland, R. K.; Hackett, B. R.; Hallin, A. L.; Haranczyk, M.; Harrop, B.; Hoppe, E. W.; Horikawa, S.; Hosseini, B.; Hubaut, F.; Humble, P.; Hungerford, E.; Ianni, An.; Ilyasov, A.; Ippolito, V.; Jillings, C.; Keeter, K. J.; Kendziora, C. L.; Kochanek, I.; Kondo, Kazuhiro; Köpp, G.; Korablëv, D.; Korga, G.; Kubankin, A. S.; Kugathasan, R.; Kuss, M.; Commara, M. La; Delfa, L. La; Laí, M.; Lebois, M.; Lehnert, B.; Levashko, N.; Li, X.; Liqiang, Q.; Lissia, M.; Lodi, Gabriele; Longo, Giuseppe; Lussana, Rudi; Luzzi, L.; Machado, A. A.; Machulin, I.; Mandarano, A.; Manecki, S.; Mapelli, L.; Margotti, A.; Mari, Stefano Maria; Mariani, Mario; Maricic, J.; Marinelli, M.; Marras, D.; Martínez, M. Lucio; Martinez, M.; Mascia, Michele; Mason, James Paul; Masoni, A.; McDonald, A. B.; Messina, A.; Miletic, T.; Milinčić, R.; Moggi, A.; Moioli, Stefania; Monroe, J.; Morrocchi, M.; Mróz, Tomasz; Mu, Wei; Muratova, V.; Murphy, S.; Musico, P.; Nania, R.; Napolitano, T.; Agasson, A. Navrer; Nessi, M.; Nikulin, Ilya; Nosov, V. V.; Nowak, J.; Oleinik, A.; Oleynikov, V.; Orsini, M.; Ortica, F.; Pagani, L.; Pallavicini, M.; Palmas, Simonetta; Pandola, L.; Pantic, E.; Paoloni, E.; Pazzona, Federico G.; Peeters, S. J. M.; Pelczar, K.; Pellegrini, Laura; Pellegrino, C.; Pelliccia, N.; Perotti, F.; Pesudo, V.; Picciau, E.; Pietropaolo, F.; Pocar, A.; Pollmann, T. R.; Portaluppi, Davide; Poudel, S. S.; Pralavorio, P.; Price, D.; Radics, B.; Raffaelli, F.; Ragusa, F.; Razeti, M.; Regenfus, C.; Renshaw, A.; Rescia, S.; Rescigno, M.; Retière, F.; Rignanese, L. P.; Ripoli, C.; Rivetti, A.; Rode, J.; Romani, A.; Romero, L.; Rossi, N.; Rubbia, A.; Sala, P.; Salatino, Piero; Samoylov, O.; García, E.; Sandford, Emily; Sanfilippo, Simone; Sant, Marco; Santone, D.; Santorelli, R.; Savarese, C.; Scapparone, E.; Schlitzer, B.; Scioli, G.; Segreto, E.; Seifert, Allen; Semenov, D.; Shchagin, A. V.; Sheshukov, A.; Siddhanta, S.; Simeone, M.; Singh, Prabhjot; Skensved, P.; Skorokhvatov, M.; Smirnov, O.; Sobrero, G.; Sokolov, A.; Sotnikov, A.; Stainforth, R.; Steri, A.; Stracka, S.; Strickland, V.; Suffritti, G.B.; Sulis, Sara; Suvorov, Y.; Szelc, A. M.; Tartaglia, R.; Testera, G.; Thorpe, T.; Tonazzo, A.; Tosi, Alberto; Tuveri, Matteo; Unzhakov, E.; Usai, G. L.; Vacca, Annalisa; Vázquez‐Jáuregui, E.; Viant, T.; Viel, S.; Villa, Federica; Vishneva, A.; Vogelaar, R. B.; Wahl, Jon H.; Walding, J.; Wang, H.; Wang, Y.; Westerdale, S.; Wheadon, R.; Williams, R.; Wilson, J. S.; Wójcik, M.; Wu, S.; Xiao, Xiang; Yang, Chengfeng; Ye, Z.; Zuffa, M.; Zuzel, G.

doi:10.1140/epjc/s10052-020-08801-2

Cited by 29 publications

(27 citation statements)

References 50 publications

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“…Optical readout of dual-phase LArTPCs offers an alternative approach to the existing and previously described charge readout methodology. As noted previously in Section 3, Townsend multiplication occurring in the THGEM/LEM holes not only produces additional electrons, but also secondary scintillation light (hereafter denoted by "S2"), and studies have shown that-depending on the exact amplification field across the THGEM/LEMmany hundreds of S2 photons can be produced for every drift electron [85][86][87][88][89]. Optical readout therefore relates to the detection of these S2 photons.…”

Section: Optical Readout and The Ariadne Programmentioning

confidence: 94%

“…Although there are a wide variety of photo-sensitive detectors available with which to observe the S2 light, one of the key requirements for use in a neutrino detector must be the capability for high resolution tracking and position reconstruction, as previously noted in Section 3. With this in mind, in recent years devices such as commercial SiPMs [85,89] and CCDs ("charge-coupled devices") [90] have been used to optically read out smallscale dual-phase LArTPCs, and linearly graded SiPMs ("LG-SiPMs") have also shown potential following initial tests conducted in a gaseous TPC [91]. (LG-SiPMs are a relatively new type of SiPM that natively produces 3D position information using a combination of 2D microcell sensor structure and nanosecond timing resolution [92].)…”

Section: Optical Readout and The Ariadne Programmentioning

confidence: 99%

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Review of Liquid Argon Detector Technologies in the Neutrino Sector

Majumdar

Mavrokoridis

2021

Applied Sciences

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Liquid Argon (LAr) is one of the most widely used scintillators in particle detection, due to its low cost, high availability and excellent scintillation properties. A large number of experiments in the neutrino sector are based around using LAr in one or more Time Projection Chambers (TPCs), leading to high resolution three-dimensional particle reconstruction. In this paper, we review and summarise a number of these Liquid Argon Time Projection Chamber (LArTPC) experiments, and briefly describe the specific technologies that they currently employ. This includes single phase LAr experiments (ICARUS T600, MicroBooNE, SBND, LArIAT, DUNE-SP, ProtoDUNE-SP, ArgonCube and Vertical Drift) and dual phase LAr experiments (DUNE-DP, WA105, ProtoDUNE-DP and ARIADNE). We also discuss some new avenues of research in the field of LArTPC readout, which show potential for wide-scale use in the near future.

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Section: Optical Readout and The Ariadne Programmentioning

confidence: 94%

Section: Optical Readout and The Ariadne Programmentioning

confidence: 99%

Review of Liquid Argon Detector Technologies in the Neutrino Sector

Majumdar

Mavrokoridis

2021

Applied Sciences

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“…4 Photon emission spectra in gaseous Ar due to excimer scintillations in the VUV measured in [15], NBrS EL at 8.3 Td theoretically calculated in [4] and atomic scintillations in the NIR measured in [16,17]. Also shown is the photon detection efficiency (PDE) of the typical SiPM [18] It has a line emission spectrum [3,16] (see Fig. 4) and a ∼1 Td higher electric field threshold compared to excimer EL, i.e.…”

Section: Overview Of Electroluminescence (El) Mechanisms In Noble Gasesmentioning

confidence: 94%

Neutral bremsstrahlung and excimer electroluminescence in noble gases and its relevance to two-phase dark matter detectors

Borisova

2021

Eur. Phys. J. C

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Proportional electroluminescence (EL) is the physical effect used in two-phase detectors for dark matter searches, to optically record (in the gas phase) the ionization signal produced by particle scattering in the liquid phase. In our previous work the presence of a new EL mechanism, namely that of neutral bremsstrahlung (NBrS), was demonstrated in two-phase argon detectors both theoretically and experimentally, in addition to the ordinary EL mechanism due to excimer emission. In this work the similar theoretical approach is applied to all noble gases, i.e. overall to helium, neon, argon, krypton and xenon, to calculate the EL yields and spectra both for NBrS and excimer EL. The relevance of the results obtained to the development of two-phase dark matter detectors is discussed.

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“…The ReD TPC shares several key characteristics of the future DarkSide-20k experiment, including some elements of the mechanical design, but on a smaller scale. The main technological advance is a readout system based entirely on SiPMs, which offer the possibility of a higher photon detection efficiency relative to typical cryogenic photomultipliers [4,12,13]. The ReD detector discussed here is the first double-phase argon TPC read out by SiPMs to be stably operated on the time scale of months and fully characterised with neutron and γ sources.…”

Section: Introductionmentioning

confidence: 99%

“…Fig 13. Measured S1 distribution from a 83m Kr calibration run with E d = 183 V/cm, superimposed with the normalised environmental background and the best fit to a template (Monte Carlo signal + background data) that accounts for detector resolution.…”

mentioning

confidence: 99%

Performance of the ReD TPC, a novel double-phase LAr detector with silicon photomultiplier readout

et al. 2021

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A double-phase argon Time Projection Chamber (TPC), with an active mass of 185 g, has been designed and constructed for the Recoil Directionality (ReD) experiment. The aim of the ReD project is to investigate the directional sensitivity of argon-based TPCs via columnar recombination to nuclear recoils in the energy range of interest (20–$$200\,\hbox {keV}_{nr}$$ 200 keV nr ) for direct dark matter searches. The key novel feature of the ReD TPC is a readout system based on cryogenic Silicon Photomultipliers (SiPMs), which are employed and operated continuously for the first time in an argon TPC. Over the course of 6 months, the ReD TPC was commissioned and characterised under various operating conditions using $$\gamma $$ γ -ray and neutron sources, demonstrating remarkable stability of the optical sensors and reproducibility of the results. The scintillation gain and ionisation amplification of the TPC were measured to be $$g_1 = (0.194 \pm 0.013)$$ g 1 = ( 0.194 ± 0.013 ) photoelectrons/photon and $$g_2 = (20.0 \pm 0.9)$$ g 2 = ( 20.0 ± 0.9 ) photoelectrons/electron, respectively. The ratio of the ionisation to scintillation signals (S2/S1), instrumental for the positive identification of a candidate directional signal induced by WIMPs, has been investigated for both nuclear and electron recoils. At a drift field of 183 V/cm, an S2/S1 dispersion of 12% was measured for nuclear recoils of approximately 60–$$90\,\hbox {keV}_{nr}$$ 90 keV nr , as compared to 18% for electron recoils depositing 60 keV of energy. The detector performance reported here meets the requirements needed to achieve the principal scientific goals of the ReD experiment in the search for a directional effect due to columnar recombination. A phenomenological parameterisation of the recombination probability in LAr is presented and employed for modeling the dependence of scintillation quenching and charge yield on the drift field for electron recoils between 50–500 keV and fields up to 1000 V/cm.

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SiPM-matrix readout of two-phase argon detectors using electroluminescence in the visible and near infrared range

Cited by 29 publications

References 50 publications

Review of Liquid Argon Detector Technologies in the Neutrino Sector

Review of Liquid Argon Detector Technologies in the Neutrino Sector

Neutral bremsstrahlung and excimer electroluminescence in noble gases and its relevance to two-phase dark matter detectors

Performance of the ReD TPC, a novel double-phase LAr detector with silicon photomultiplier readout

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