Measuring low energy atmospheric neutrino spectra with the JUNO detector

Angel Abusleme,Thomas Adam,Shakeel Ahmad,Rizwan Ahmed,S. Aiello,Muhammad Akram,Fengpeng An,Guangpeng An,Q. An,Giuseppe Andronico,Н. Анфимов,Vito Antonelli,Tatiana Antoshkina,B. Asavapibhop, J. P. A. M. de André,Didier Auguste,Andrej Babič,W. Baldini,Andrea Barresi,E. Baussan,M. Bellato,Antonio Bergnoli,E. Bernieri,Thilo Birkenfeld,Sylvie Blin,D. Blum,S. Blyth,Anastasia Bolshakova,M. Bongrand,Clément Bordereau,D. Bretón,A. Brigatti,R. Brugnera,Riccardo Bruno,A. Budano,Mario Buscemi,J. Busto,Ilya Butorov,A. Cabrera,H. Cai,X. Cai,Yanke Cai,Zhiyan Cai,Antonio Cammi,Agustín Campeny,Chuanya Cao,G. F. Cao,Jun Cao,R. Caruso, C. Cerna,J. F. Chang,Yun Hsuan Chang,Pingping Chen,Po‐An Chen,Shaomin Chen,Xurong Chen,Yiwen Chen,Yixue Chen,Yu Chen,Zhang Chen,Jie Cheng,Yaping Cheng,Alexey Chetverikov,D. Chiesa,P. Chimenti,A. Chukanov,Gérard Claverie,Catia Clementi, B. Clerbaux,Selma Conforti Di Lorenzo,Daniele Corti,S. Costa,F. Dal Corso,Olivia Dalager,C. De La Taille,J. Deng,Zhi Deng,Z. Y. Deng,Wilfried Depnering,M. Fernandez Diaz,Xuefeng Ding,Yayun Ding,Bayu Dirgantara,Sergey Dmitrievsky,Tadeáš Dohnal,Dmitry Dolzhikov,Georgy Donchenko,Jianmeng Dong,E. Doroshkevich,M. Dracos, F. Druillole,S. X. Du,S. Dusini,Martin Dvořák,T. Enqvist,Heike Enzmann,Andrea Fabbri, L. Fajt,Donghua Fan,Lei Fan,Can Fang,J. Fang,W. Fang,Marco Fargetta,Dmitry Fedoseev,V. Fekete,Li‐Cheng Feng,Qichun Feng,R. Ford, A. Formozov,Amélie Fournier,Haonan Gan,Feng Gao,A. Garfagnini, Christoph Genster,M. Giammarchi, A. Giaz,Nunzio Giudice,M. Gonchar,Guanghua Gong,H. Gong,O.E. Gorchakov,Yuri Gornushkin,Alexandre Göttel,M. Grassi,Christian Grewing,Vasily Gromov,M. H. Gu,Xiaofei Gu,Yu Gu,Mengyun Guan,Nunzio Guardone, Maria Gul,Cong Guo,Jingyuan Guo,Wanlei Guo,Xin-Heng Guo,Yuhang Guo,Paul Hackspacher,C. Hagner,Ran Han,Yang Han,Muhammad Sohaib Hassan, M. He,Wei He,Tobias Heinz,Patrick Hellmuth,Y. K. Heng,Rafael Herrera, Daojin Hong,YuenKeung Hor,Shaojing Hou, Y. Hsiung,Bei-Zhen Hu,H. Hu,Jianrun Hu,Jun Hu,Shouyang Hu, T. Hu,Zhuojun Hu,Chunhao Huang,Guihong Huang,Hanxiong Huang,Qinhua Huang,Wenhao Huang,X. T. Huang,X. T. Huang,Yongbo Huang,Jiaqi Hui, L. Huo,Wenju Huo,Cédric Huss,Safeer Hussain, A. Insolia,Ara Ioannisian,R. Isocrate,Beatrice Jelmini, K. L. Jen,Ignacio Jeria,Xiaolu Ji,Xingzhao Ji,Huihui Jia,J. Jia,Siyu Jian,Di Jiang,X. S. Jiang,Ruyi Jin,Xiaoping Jing, C. Jollet, Jari Joutsenvaara,Sirichok Jungthawan,Leonidas Kalousis,Philipp Kampmann, Kang Li,M. Karagounis,Narine Kazarian,W. A. Khan,K. Khosonthongkee,D. Korablëv,Konstantin Kouzakov,A. Krasnoperov, Z. V. Krumshteyn, A. Kruth,Nikolay Kutovskiy,P. Kuusiniemi,T. Lachenmaier,Cecilia Landini,Sébastien Leblanc,Victor Lebrin,F. Lefèvre,Ruiting Lei,R. Leitner,J. K. C. Leung,Demin Li,Fĕi Li,Fule Li,Haitao Li,Huiling Li,Jiaqi Li,Mengzhao Li, Min Li,Nan Li,Qingjiang Li,Ruhui Li,Shanfeng Li,Tao Li,Weidong Li,Weiguo Li,Xiaomei Li,Xiaonan Li,Xinglong Li, Yang Li,Yufeng Li,Zhaohan Li,Zhibing Li,Ziyuan Li,H. Liang,Jingjing Liang,Daniel Liebau,A. Limphirat,Sukit Limpijumnong,Guey-Lin Lin,Shengxin Lin,Lin Tao,Jiajie Ling,I. Lippi, Fang Liu,Haidong Liu,Hongbang Liu,Hongjuan Liu,Hongtao Liu,Hui Liu,Jianglai Liu,Jinchang Liu,Min Liu,Qian Liu,Qin Liu,Runxuan Liu,Shuangyu Liu,Shubin Liu,Shulin Liu,Xiaowei Liu,Xiwen Liu,Yan Liu,Yunzhe Liu,Alexey Lokhov,P. Lombardi,Claudio Lombardo,Kai Loo,C. Lu,Haoqi Lu,Jingbin Lu,Junguang Lu,Shuxiang Lu,Xiaoxu Lu,Б. Лубсандоржиев,Sultim Lubsandorzhiev,L. Ludhová,Fengjiao Luo,Guang Luo,P. W. Luo,Shu Luo,W. Luo,V. I. Lyashuk,Bangzheng Ma,Q. M. Ma, Songde Ma,Xiaoyan Ma,Xubo Ma,Jihane Maalmi,Yury Malyshkin,Fabio Mantovani,Francesco Manzali,Xin Mao,Y. Mao,Stefano Maria Mari,Filippo Marini,Sadia Marium,Cristina Martellini,Gisèle Martin-Chassard,A. Martini,Davit Mayilyan,Ints Mednieks,Y. Meng,A. Meregaglia,E. Meroni,David Meyhöfer, M. Mezzetto,J. Miller,L. Miramonti,Salvatore Monforte,P. Montini,M. Montuschi,Axel Müller,Pavithra Muralidharan,M. Nastasi,D. Naumov,Е. Наумова,D. Navas-Nicolás,I. Nemchenok,Minh Thuan Nguyen Thi,Feipeng Ning, Z. Ning,Hiroshi Nunokawa, L. Oberauer,J. P. Ochoa-Ricoux,A. Olshevskiy,D. Orestano,F. Ortica,Rainer Othegraven,Hsiao-Ru Pan,A. Paoloni,Nina Parkalian,S. Parmeggiano,Yatian Pei, N. Pelliccia,Anguo Peng,H. Peng, F. Perrot,Pierre-Alexandre Petitjean,F. Petrucci,Oliver Pilarczyk,Luis Felipe Piñeres Rico,A. Popov,Pascal Poussot,Wathan Pratumwan,E. Previtali,F. Z. Qi,M. Qi, S. Qian,Xiaohui Qian,Z. Qian, Hui Qiao,Z. H. Qin,Shoukang Qiu,Muhammad Usman Rajput, G. Ranucci, N. Raper,A. Re,Henning Rebber,Abdel Rebii, Biying Ren,Jie Ren,Taras Rezinko,B. Ricci,Markus Robens,Mathieu Roche,Narongkiat Rodphai,Aldo Romani, B. Roskovec,Christian Roth,X. D. Ruan,Xichao Ruan,Saroj Rujirawat,А. Рыбников,A. Sadovsky,Paolo Saggese, G. Salamanna,Simone Sanfilippo,Anut Sangka,Nuanwan Sanguansak,U. Sawangwit,Julia Sawatzki,Fatma Sawy,Michaela Schever,J. Schuler,Cédric Schwab,Konstantin Schweizer,A. Selyunin,Andrea Serafini,Giulio Settanta,M. Settimo,Zhuang Shao,Vladislav Sharov,Arina Shaydurova, John Shi,Yanan Shi,Vitaly Shutov,A. Sidorenkov, F. Šimkovic,C. Sirignano,Jaruchit Siripak,M. Sisti,M. Słupecki,Mikhail Smirnov, O. Smirnov,Thiago Sogo-Bezerra,Sergey Sokolov,Julanan Songwadhana,Boonrucksar Soonthornthum,A. Sotnikov,Ondřej Šrámek,Warintorn Sreethawong, A. Stahl,L. Stančo,Konstantin Stankevich,Dušan Štefánik,Hans Steiger,Jochen Steinmann,Tobias Sterr,Matthias Raphael Stock,Virginia Strati,Alexander Studenikin,G. X. Sun,Shifeng Sun,Xilei Sun,Y. Z. Sun,Y. J. Sun,N. Suwonjandee,Michal Szelezniak, J. Tang,Qiang Tang,Quan Tang,Xiao Tang,Alexander Tietzsch, I. Tkachev,Tomáš Tměj,Konstantin Treskov,A. Triossi,Giancarlo Troni,W. H. Trzaska,C. Tuvé,Н. Ушаков,Johannes van den Boom,Stefan van Waasen,Guillaume Vanroyen, N. Vassilopoulos,Vadim Vedin,G. Verde,Maxim Vialkov,B. Viaud,Moritz Vollbrecht,Cristina Volpe, V. Vorobel,Д. Воронин,L. Votano,Pablo Walker,Caishen Wang,Chung-Hsiang Wang,En Wang,Guoli Wang,Jian Wang,Jun Wang,Kunyu Wang,Lu Wang,Meifen Wang,Meng Wang,Ruiguang Wang,Siguang Wang,Wei Wang,Wenshuai Wang,Xi Wang,Xiangyue Wang,Yangfu Wang,Yaoguang Wang,Yi Wang,Yifang Wang,Yuanqing Wang,Yuman Wang, Zhe Wang, Zheng Wang,Zhimin Wang,Zongyi Wang,M. Waqas,Apimook Watcharangkool,Lianghong Wei,Wei Wei,Wenlu Wei,Yadong Wei,L. Wen,Christopher Wiebusch, Steven Chan-Fai Wong,Bjoern Wonsak,Diru Wu,Fangliang Wu,Qun Wu, W. Wu, Zhi Wang,M. Wurm,Jacques Wurtz,Christian Wysotzki,Yufei Xi,Dongmei Xia,Y. Xie,Z. Xie,Zhi-zhong Xing,Benda Xu,C. Xu,D. L. Xu,Fanrong Xu,Hangkun Xu,Jilei Xu, Jing Xu,M. Xu, Y. Xu, Yunlin Xu,Baojun Yan,Taylor Yan, Yan Wu,Xiongbo Yan,Yupeng Yan,Anbo Yang,Changgen Yang,H. X. Yang,Jie Yang,Lei Yang,Xiaoyu Yang,Yifan Yang,Haifeng Yao, Z. Yasin,Jiaxuan Ye,Mei Ye,Ziping Ye, Ugur Yegin, F. Yermia, Peihuai Yi,Na Yin,Xiangwei Yin, You Zhou, B. X. Yu,Chiye Yu,C. X. Yu,Hongzhao Yu,M. Yu,Xianghui Yu,Zeyuan Yu,Zezhong Yu,C. Z. Yuan,Ying Yuan,Zhenxiong Yuan,Ziyi Yuan,Baobiao Yue,Noman Zafar,André Zambanini,Vitalii Zavadskyi,S. Zeng,Tingxuan Zeng,Yuda Zeng,Liang Zhan,Aiqiang Zhang,Feiyang Zhang,Guoqing Zhang,Haiqiong Zhang,Honghao Zhang,Jiawen Zhang,Jie Zhang,Jingbo Zhang,Jinnan Zhang,Peng Zhang,Qingmin Zhang,Shiqi Zhang,Shu Zhang,Tao Zhang,Xiaomei Zhang,Xuantong Zhang,Xueyao Zhang,Yan Zhang,Yinhong Zhang,Yiyu Zhang,Yongpeng Zhang,Yuanyuan Zhang,Yumei Zhang,Zhenyu Zhang,Zhijian Zhang,Fengyi Zhao,J. Zhao,Rong Zhao,S. J. Zhao,T. C. Zhao,Dongqin Zheng,Hua Zheng,Minshan Zheng,Y. Zheng,Wei-Rong Zhong,Jing Zhou, Zhou Li,Nan Zhou,Shun Zhou,Tong Zhou,Xiang Zhou,Jiang Zhu,K. Zhu,Z. A. Zhu, B. A. Zhuang,H. L. Zhuang,Liang Zong,J. H. Zou

arXiv (Cornell University)（2021）

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摘要

Atmospheric neutrinos are one of the most relevant natural neutrino sources that can be exploited to infer properties about Cosmic Rays and neutrino oscillations. The Jiangmen Underground Neutrino Observatory (JUNO) experiment, a 20 kton liquid scintillator detector with excellent energy resolution is currently under construction in China. JUNO will be able to detect several atmospheric neutrinos per day given the large volume. A study on the JUNO detection and reconstruction capabilities of atmospheric $\nu_e$ and $\nu_\mu$ fluxes is presented in this paper. In this study, a sample of atmospheric neutrinos Monte Carlo events has been generated, starting from theoretical models, and then processed by the detector simulation. The excellent timing resolution of the 3 PMT light detection system of JUNO detector and the much higher light yield for scintillation over Cherenkov allow to measure the time structure of the scintillation light with very high precision. Since $\nu_e$ and $\nu_\mu$ interactions produce a slightly different light pattern, the different time evolution of light allows to discriminate the flavor of primary neutrinos. A probabilistic unfolding method has been used, in order to infer the primary neutrino energy spectrum from the detector experimental observables. The simulated spectrum has been reconstructed between 100 MeV and 10 GeV, showing a great potential of the detector in the atmospheric low energy region.

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atmospheric neutrino,juno detector,spectra

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