標題: | Neutrino physics with JUNO |
作者: | An, Fengpeng An, Guangpeng An, Qi Antonelli, Vito Baussan, Eric Beacom, John Bezrukov, Leonid Blyth, Simon Brugnera, Riccardo Avanzini, Margherita Buizza Busto, Jose Cabrera, Anatael Cai, Hao Cai, Xiao Cammi, Antonio Cao, Guofu Cao, Jun Chang, Yun Chen, Shaomin Chen, Shenjian Chen, Yixue Chiesa, Davide Clemenza, Massimiliano Clerbaux, Barbara Conrad, Janet D\'Angelo, Davide De Kerret, Herve Deng, Zhi Deng, Ziyan Ding, Yayun Djurcic, Zelimir Dornic, Damien Dracos, Marcos Drapier, Olivier Dusini, Stefano Dye, Stephen Enqvist, Timo Fan, Donghua Fang, Jian Favart, Laurent Ford, Richard Goeger-Neff, Marianne Gan, Haonan Garfagnini, Alberto Giammarchi, Marco Gonchar, Maxim Gong, Guanghua Gong, Hui Gonin, Michel Grassi, Marco Grewing, Christian Guan, Mengyun Guarino, Vic Guo, Gang Guo, Wanlei Guo, Xin-Heng Hagner, Caren Han, Ran He, Miao Heng, Yuekun Hsiung, Yee Hu, Jun Hu, Shouyang Hu, Tao Huang, Hanxiong Huang, Xingtao Huo, Lei Ioannisian, Ara Jeitler, Manfred Ji, Xiangdong Jiang, Xiaoshan Jollet, Cecile Kang, Li Karagounis, Michael Kazarian, Narine Krumshteyn, Zinovy Kruth, Andre Kuusiniemi, Pasi Lachenmaier, Tobias Leitner, Rupert Li, Chao Li, Jiaxing Li, Weidong Li, Weiguo Li, Xiaomei Li, Xiaonan Li, Yi Li, Yufeng Li, Zhi-Bing Liang, Hao Lin, Guey-Lin Lin, Tao Lin, Yen-Hsun Ling, Jiajie Lippi, Ivano Liu, Dawei Liu, Hongbang Liu, Hu Liu, Jianglai Liu, Jianli Liu, Jinchang Liu, Qian Liu, Shubin Liu, Shulin Lombardi, Paolo Long, Yongbing Lu, Haoqi Lu, Jiashu Lu, Jingbin Lu, Junguang Lubsandorzhiev, Bayarto Ludhova, Livia Luo, Shu Lyashuk, Vladimir Moellenberg, Randolph Ma, Xubo Mantovani, Fabio Mao, Yajun Mari, Stefano M. McDonough, William F. Meng, Guang Meregaglia, Anselmo Meroni, Emanuela Mezzetto, Mauro Miramonti, Lino Mueller, Thomas Naumov, Dmitry Oberauer, Lothar Ochoa-Ricoux, Juan Pedro Olshevskiy, Alexander Ortica, Fausto Paoloni, Alessandro Peng, Haiping Peng, Jen-Chieh Previtali, Ezio Qi, Ming Qian, Sen Qian, Xin Qian, Yongzhong Qin, Zhonghua Raffelt, Georg Ranucci, Gioacchino Ricci, Barbara Robens, Markus Romani, Aldo Ruan, Xiangdong Ruan, Xichao Salamanna, Giuseppe Shaevitz, Mike Sinev, Valery Sirignano, Chiara Sisti, Monica Smirnov, Oleg Soiron, Michael Stahl, Achim Stanco, Luca Steinmann, Jochen Sun, Xilei Sun, Yongjie Taichenachev, Dmitriy Tang, Jian Tkachev, Igor Trzaska, Wladyslaw Van Waasen, Stefan Volpe, Cristina Vorobel, Vit Votano, Lucia Wang, Chung-Hsiang Wang, Guoli Wang, Hao Wang, Meng Wang, Ruiguang Wang, Siguang Wang, Wei Wang, Yi Wang, Yi Wang, Yifang Wang, Zhe Wang, Zheng Wang, Zhigang Wang, Zhimin Wei, Wei Wen, Liangjian Wiebusch, Christopher Wonsak, Bjoern Wu, Qun Wulz, Claudia-Elisabeth Wurm, Michael Xi, Yufei Xia, Dongmei Xie, Yuguang Xing, Zhi-Zhong Xu, Jilei Yan, Baojun Yang, Changgen Yang, Chaowen Yang, Guang Yang, Lei Yang, Yifan Yao, Yu Yegin, Ugur Yermia, Frederic You, Zhengyun Yu, Boxiang Yu, Chunxu Yu, Zeyuan Zavatarelli, Sandra Zhan, Liang Zhang, Chao Zhang, Hong-Hao Zhang, Jiawen Zhang, Jingbo Zhang, Qingmin Zhang, Yu-Mei Zhang, Zhenyu Zhao, Zhenghua Zheng, Yangheng Zhong, Weili Zhou, Guorong Zhou, Jing Zhou, Li Zhou, Rong Zhou, Shun Zhou, Wenxiong Zhou, Xiang Zhou, Yeling Zhou, Yufeng Zou, Jiaheng 物理研究所 Institute of Physics |
關鍵字: | reactor neutrino experiments;large scintillator detectors;neutrino physics;neutrino astronomy |
公開日期: | 三月-2016 |
摘要: | The Jiangmen Underground Neutrino Observatory (JUNO), a 20 kton multipurpose underground liquid scintillator detector, was proposed with the determination of the neutrino mass hierarchy (MH) as a primary physics goal. The excellent energy resolution and the large fiducial volume anticipated for the JUNO detector offer exciting opportunities for addressing many important topics in neutrino and astro-particle physics. In this document, we present the physics motivations and the anticipated performance of the JUNO detector for various proposed measurements. Following an introduction summarizing the current status and open issues in neutrino physics, we discuss how the detection of antineutrinos generated by a cluster of nuclear power plants allows the determination of the neutrino MH at a 3-4 sigma significance with six years of running of JUNO. The measurement of antineutrino spectrum with excellent energy resolution will also lead to the precise determination of the neutrino oscillation parameters sin(2) theta(12), Delta m(21)(2), and vertical bar Delta m(ee)(2)vertical bar to an accuracy of better than 1%, which will play a crucial role in the future unitarity test of the MNSP matrix. The JUNO detector is capable of observing not only antineutrinos from the power plants, but also neutrinos/antineutrinos from terrestrial and extra-terrestrial sources, including supernova burst neutrinos, diffuse supernova neutrino background, geoneutrinos, atmospheric neutrinos, and solar neutrinos. As a result of JUNO\'s large size, excellent energy resolution, and vertex reconstruction capability, interesting new data on these topics can be collected. For example, a neutrino burst from a typical core-collapse supernova at a distance of 10 kpc would lead to similar to 5000 inverse-beta-decay events and similar to 2000 all-flavor neutrino-proton ES events in JUNO, which are of crucial importance for understanding the mechanism of supernova explosion and for exploring novel phenomena such as collective neutrino oscillations. Detection of neutrinos from all past core-collapse supernova explosions in the visible universe with JUNO would further provide valuable information on the cosmic star-formation rate and the average core-collapse neutrino energy spectrum. Antineutrinos originating from the radioactive decay of uranium and thorium in the Earth can be detected in JUNO with a rate of similar to 400 events per year, significantly improving the statistics of existing geoneutrino event samples. Atmospheric neutrino events collected in JUNO can provide independent inputs for determining the MH and the octant of the theta(23) mixing angle. Detection of the Be-7 and B-8 solar neutrino events at JUNO would shed new light on the solar metallicity problem and examine the transition region between the vacuum and matter dominated neutrino oscillations. Regarding light sterile neutrino topics, sterile neutrinos with 10-(5) eV(2) < Delta m(41)(2) < 10(-2) and a sufficiently large mixing angle theta(14) could be identified through a precise measurement of the reactor antineutrino energy spectrum. Meanwhile, JUNO can also provide us excellent opportunities to test the eV-scale sterile neutrino hypothesis, using either the radioactive neutrino sources or a cyclotron-produced neutrino beam. The JUNO detector is also sensitive to several other beyondthe-standard-model physics. Examples include the search for proton decay via the p -> K++ <(v)over bar> decay channel, search for neutrinos resulting from dark-matter annihilation in the Sun, search for violation of Lorentz invariance via the sidereal modulation of the reactor neutrino event rate, and search for the effects of non-standard interactions. The proposed construction of the JUNO detector will provide a unique facility to address many outstanding crucial questions in particle and astrophysics in a timely and cost-effective fashion. It holds the great potential for further advancing our quest to understanding the fundamental properties of neutrinos, one of the building blocks of our Universe. |
URI: | http://dx.doi.org/10.1088/0954-3899/43/3/030401 http://hdl.handle.net/11536/133518 |
ISSN: | 0954-3899 |
DOI: | 10.1088/0954-3899/43/3/030401 |
期刊: | JOURNAL OF PHYSICS G-NUCLEAR AND PARTICLE PHYSICS |
Volume: | 43 |
Issue: | 3 |
顯示於類別: | 期刊論文 |