Measurement of the cosmogenic neutron yield in Super-Kamiokande with gadolinium loaded water

Super-Kamiokande Collaboration, :,M. Shinoki,K. Abe,Y. Hayato,K. Hiraide, K. Hosokawa,K. Ieki,M. Ikeda,J. Kameda,Y. Kanemura, R. Kaneshima,Y. Kashiwagi,Y. Kataoka,S. Miki,S. Mine,M. Miura,S. Moriyama,Y. Nakano,M. Nakahata,S. Nakayama,Y. Noguchi,K. Okamoto,K. Sato,H. Sekiya,H. Shiba,K. Shimizu,M. Shiozawa,Y. Sonoda,Y. Suzuki,A. Takeda,Y. Takemoto,A. Takenaka,H. Tanaka,S. Watanabe,T. Yano,S. Han,T. Kajita,K. Okumura,T. Tashiro,T. Tomiya,X. Wang,S. Yoshida,G. D. Megias,P. Fernandez,L. Labarga,N. Ospina,B. Zaldivar,B. W. Pointon,E. Kearns,J. L. Raaf,L. Wan,T. Wester,J. Bian,N. J. Griskevich,W. R. Kropp,S. Locke,M. B. Smy,H. W. Sobel,V. Takhistov,A. Yankelevich,J. Hill,S. H. Lee,D. H. Moon,R. G. Park,B. Bodur,K. Scholberg,C. W. Walter,A. Beauchêne,L. Bernard,A. Coffani,O. Drapier,S. El Hedri,A. Giampaolo,Th. A. Mueller,A. D. Santos,P. Paganini,B. Quilain,T. Ishizuka,T. Nakamura,J. S. Jang,J. G. Learned,K. Choi,S. Cao,L. H. V. Anthony,D. Martin,M. Scott,A. A. Sztuc,Y. Uchida,V. Berardi,M. G. Catanesi,E. Radicioni,N. F. Calabria,A. Langella,L. N. Machado,G. De Rosa,G. Collazuol,F. Iacob,M. Lamoureux,M. Mattiazzi,L. Ludovici,M. Gonin,G. Pronost, C. Fujisawa,Y. Maekawa,Y. Nishimura,R. Akutsu,M. Friend,T. Hasegawa,T. Ishida, T. Kobayashi,M. Jakkapu,T. Matsubara,T. Nakadaira, K. Nakamura,Y. Oyama,K. Sakashita,T. Sekiguchi,T. Tsukamoto, N. Bhuiyan,T. Boschi, G. T. Burton,F. Di Lodovico,J. Gao,A. Goldsack,T. Katori,J. Migenda,M. Taani,Z. Xie,S. Zsoldos, Y. Kotsar,H. Ozaki,A. T. Suzuki,Y. Takeuchi,C. Bronner,J. Feng,T. Kikawa,M. Mori,T. Nakaya,R. A. Wendell,K. Yasutome,S. J. Jenkins,N. McCauley,P. Mehta,A. Tarrant,K. M. Tsui,Y. Fukuda,Y. Itow,H. Menjo,K. Ninomiya,J. Lagoda,S. M. Lakshmi,M. Mandal,P. Mijakowski,Y. S. Prabhu,J. Zalipska,M. Jia,J. Jiang,C. K. Jung,M. J. Wilking,C. Yanagisawa,M. Harada,H. Ishino,S. Ito,H. Kitagawa,Y. Koshio,F. Nakanishi,S. Sakai,G. Barr,D. Barrow,L. Cook,S. Samani,D. Wark,A. Holin,F. Nova,J. Y. Yang,B. S. Yang,J. Yoo,J. E. P. Fannon, L. Kneale,M. Malek,J. M. McElwee, O. Stone,M. D. Thiesse,L. F. Thompson,H. Okazawa,S. B. Kim,E. Kwon,J. W. Seo,I. Yu,A. K. Ichikawa,K. D. Nakamura,S. Tairafune,K. Nishijima,M. Koshiba,K. Iwamoto,K. Nakagiri,Y. Nakajima, S. Shima,N. Taniuchi,M. Yokoyama,K. Martens,P. de Perio,M. R. Vagins,J. Xia,M. Kuze,S. Izumiyama,M. Inomoto,M. Ishitsuka,H. Ito,T. Kinoshita,R. Matsumoto,Y. Ommura,N. Shigeta,T. Suganuma,K. Yamauchi,J. F. Martin, H. A. Tanaka,T. Towstego, R. Gaur,V. Gousy-Leblanc,M. Hartz,A. Konaka,X. Li,N. W. Prouse,S. Chen,B. D. Xu,B. Zhang,M. Posiadala-Zezula,S. B. Boyd,D. Hadley,M. Nicholson,M. O'Flaherty,B. Richards,A. Ali,B. Jamieson,Ll. Marti,A. Minamino,G. Pintaudi,S. Sano,S. Suzuki,K. Wada

arxiv（2022）

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摘要

Cosmic-ray muons that enter the Super-Kamiokande detector cause hadronic showers due to spallation in water, producing neutrons and radioactive isotopes. Those are a major background source for studies of MeV-scale neutrinos and searches for rare events. Since 2020, gadolinium was introduced in the ultra-pure water in the Super-Kamiokande detector to improve the detection efficiency of neutrons. In this study, the cosmogenic neutron yield was measured using data acquired during the period after the gadolinium loading. The yield was found to be $(2.76 \pm 0.02\,\mathrm{(stat.) \pm 0.19\,\mathrm{(syst.)}}) \times 10^{-4}\,\mu^{-1} \mathrm{g^{-1} cm^{2}}$ at 259 GeV of average muon energy at the Super-Kamiokande detector.

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