Scintillator ageing of the T2K near detectors from 2010 to 2021-Reference-Cited by-同舟云学术

Scintillator ageing of the T2K near detectors from 2010 to 2021

Published:2022-10-01 Issue:10 Volume:17 Page:P10028
ISSN:1748-0221
Container-title:Journal of Instrumentation
language:
Short-container-title:J. Inst.

Author:

Abe K.,Akhlaq N.,Akutsu R.,Ali A.,Alt C.,Andreopoulos C.,Antonova M.,Aoki S.,Arihara T.,Asada Y.,Ashida Y.,Atkin E.T.,Ban S.,Barbi M.,Barker G.J.,Barr G.,Barrow D.,Batkiewicz-Kwasniak M.,Bench F.,Berardi V.,Berns L.,Bhadra S.,Blanchet A.,Blondel A.,Bolognesi S.,Bonus T.,Bordoni S.,Boyd S.B.,Bravar A.,Bronner C.,Bron S.,Bubak A.,Buizza Avanzini M.,Calabria N.F.,Cao S.,Carter A.J.,Cartwright S.L.,Catanesi M.G.,Cervera A.,Chakrani J.,Cherdack D.,Christodoulou G.,Cicerchia M.,Coleman J.,Collazuol G.,Cook L.,Cudd A.,Davydov Yu.I.,De Roeck A.,De Rosa G.,Dealtry T.,Delogu C.C.,Densham C.,Dergacheva A.,Di Lodovico F.,Dolan S.,Douqa D.,Doyle T.A.,Drapier O.,Duffy K.E.,Dumarchez J.,Dunne P.,Dygnarowicz K.,Eguchi A.,Emery-Schrenk S.,Ershova A.,Fedotov S.,Fernandez P.,Finch A.J.,Fiorentini Aguirre G.A.,Fiorillo G.,Friend M.,Fujii Y.,Fukuda Y.,Fusshoeller K.,Giganti C.,Glagolev V.,Gonin M.,Goodman E.A.G.,Gorin A.,Grassi M.,Guigue M.,Hadley D.R.,Haigh J.T.,Hamacher-Baumann P.,Harris D.A.,Hartz M.,Hasegawa T.,Hassani S.,Hastings N.C.,Hatzikoutelis A.,Hayato Y.,Hiramoto A.,Hogan M.,Holeczek J.,Holin A.,Holvey T.J.,Hong Van N.T.,Honjo T.,Iacob F.,Ichikawa A.K.,Ikeda M.,Ishida T.,Ishitsuka M.,Israel H.T.,Ives S.J.,Iwamoto K.,Izmaylov A.,Izumi N.,Jakkapu M.,Jamieson B.,Jenkins S.J.,Jesús-Valls C.,Jiang J.J.,Jonsson P.,Jung C.K.,Jurj P.B.,Kabirnezhad M.,Kaboth A.C.,Kajita T.,Kakuno H.,Kameda J.,Kasetti S.P.,Kataoka Y.,Katayama Y.,Katori T.,Kawaue M.,Kearns E.,Khabibullin M.,Khotjantsev A.,Kikawa T.,Kikutani H.,King S.,Kisiel J.,Knight A.,Kobata T.,Kobayashi T.,Koch L.,Kogan G.,Konaka A.,Kormos L.L.,Koshio Y.,Kostin A.,Kowalik K.,Kudenko Y.,Kuribayashi S.,Kurjata R.,Kutter T.,Kuze M.,La Commara M.,Labarga L.,Lachner K.,Lagoda J.,Lakshmi S.M.,Lamers James M.,Lamont I.,Lamoureux M.,Last D.,Latham N.,Laveder M.,Lawe M.,Lee Y.,Lin C.,Lindner T.,Lin S.-K.,Litchfield R.P.,Liu S.L.,Longhin A.,Long K.R.,Ludovici L.,Lu X.,Lux T.,Machado L.N.,Magaletti L.,Mahn K.,Malek M.,Mandal M.,Manly S.,Marino A.D.,Marti-Magro L.,Martin D.G.R.,Martini M.,Martin J.F.,Maruyama T.,Matsubara T.,Matveev V.,Mauger C.,Mavrokoridis K.,Mazzucato E.,McCauley N.,McElwee J.,McFarland K.S.,McGrew C.,Mefodiev A.,Megias G.D.,Mellet L.,Metelko C.,Mezzetto M.,Minamino A.,Mineev O.,Mine S.,Miura M.,Molina Bueno L.,Moriyama S.,Mueller Th.A.,Munford D.,Munteanu L.,Nagai K.,Nagai Y.,Nakadaira T.,Nakagiri K.,Nakahata M.,Nakajima Y.,Nakamura A.,Nakamura H.,Nakamura K.,Nakano Y.,Nakayama S.,Nakaya T.,Nakayoshi K.,Naseby C.E.R.,Ngoc T.V.,Nguyen V.Q.,Niewczas K.,Nishimura Y.,Nishizaki K.,Nova F.,Novella P.,Nugent J.C.,O'Keeffe H.M.,O'Sullivan L.,Odagawa T.,Ogawa T.,Okada R.,Okumura K.,Okusawa T.,Owen R.A.,Oyama Y.,Palladino V.,Paolone V.,Pari M.,Parlone J.,Parsa S.,Pasternak J.,Pavin M.,Payne D.,Penn G.C.,Perkin J.D.,Pershey D.,Pickering L.,Pidcott C.,Pintaudi G.,Pistillo C.,Popov B.,Porwit K.,Posiadala-Zezula M.,Prabhu Y.S.,Quilain B.,Radermacher T.,Radicioni E.,Radics B.,Ratoff P.N.,Reh M.,Riccio C.,Rondio E.,Roth S.,Rubbia A.,Ruggeri A.C.,Ruggles C.A.,Rychter A.,Sakashita K.,Sánchez F.,Santucci G.,Schloesser C.M.,Scholberg K.,Scott M.,Seiya Y.,Sekiguchi T.,Sekiya H.,Sgalaberna D.,Shaikhiev A.,Shaykina A.,Shiozawa M.,Shorrock W.,Shvartsman A.,Skwarczynski K.,Smy M.,Sobczyk J.T.,Sobel H.,Soler F.J.P.,Sonoda Y.,Spina R.,Su H.,Suslov I.A.,Suvorov S.,Suzuki A.,Suzuki S.Y.,Suzuki Y.,Sztuc A.A.,Tada M.,Takayasu S.,Takeda A.,Takeuchi Y.,Tanaka H.K.,Tanihara Y.,Tani M.,Tereshchenko V.V.,Teshima N.,Thamm N.,Thompson L.F.,Toki W.,Touramanis C.,Towstego T.,Tsui K.M.,Tsukamoto T.,Tzanov M.,Uchida Y.,Vacheret A.,Vagins M.,Vallari Z.,Vargas D.,Vasseur G.,Vilela C.,Vinning W.G.S.,Vladisavljevic T.,Wachala T.,Waldron A.V.,Walsh J.G.,Wang Y.,Wan L.,Wark D.,Wascko M.O.,Weber A.,Wendell R.,Wilking M.J.,Wilkinson C.,Wilson J.R.,Wood K.,Wret C.,Xia J.,Xu Y.-h.,Yamamoto K.,Yanagisawa C.,Yang G.,Yano T.,Yasutome K.,Yershov N.,Yevarouskaya U.,Yokoyama M.,Yoshimoto Y.,Yu M.,Zaki R.,Zalewska A.,Zalipska J.,Zaremba K.,Zarnecki G.,Zhao X.,Zhu T.,Ziembicki M.,Zimmerman E.D.,Zito M.,Zsoldos S.

Abstract

Abstract The T2K experiment widely uses plastic scintillator as a target for neutrino interactions and an active medium for the measurement of charged particles produced in neutrino interactions at its near detector complex. Over 10 years of operation the measured light yield recorded by the scintillator based subsystems has been observed to degrade by 0.9–2.2% per year. Extrapolation of the degradation rate through to 2040 indicates the recorded light yield should remain above the lower threshold used by the current reconstruction algorithms for all subsystems. This will allow the near detectors to continue contributing to important physics measurements during the T2K-II and Hyper-Kamiokande eras. Additionally, work to disentangle the degradation of the plastic scintillator and wavelength shifting fibres shows that the reduction in light yield can be attributed to the ageing of the plastic scintillator. The long component of the attenuation length of the wavelength shifting fibres was observed to degrade by 1.3–5.4% per year, while the short component of the attenuation length did not show any conclusive degradation.

Publisher

IOP Publishing

Subject

Mathematical Physics,Instrumentation

Link

https://iopscience.iop.org/article/10.1088/1748-0221/17/10/P10028/pdf

Reference37 articles.

1. The T2K Experiment;Abe;Nucl. Instrum. Meth. A,2011

2. Beam commissioning and operation of the J-PARC main ring synchrotron

3. The Super-Kamiokande detector;Fukuda;Nucl. Instrum. Meth. A,2003

4. Measurements of the T2K neutrino beam properties using the INGRID on-axis near detector;Abe;Nucl. Instrum. Meth. A,2012

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