Damping signatures at JUNO, a medium-baseline reactor neutrino oscillation experiment

collaboration, JUNO; Wang, Jun; Liao, Jiajun; Abusleme, Angel; Adam, Thomas; Ahmad, Shakeel; Ahmed, Rayaz; Aiello, S.; Akram, Muhammad; An, Fengpeng; An, Q.; Andronico, Giuseppe; Анфимов, Н.; Antonelli, Vito; Antoshkina, Tatiana; Asavapibhop, B.; André, J. P. A. M. de; Auguste, Didier; Babič, Andréj; Balashov, N.; Baldini, W.; Barresi, Andrea; Basilico, D.; Baussan, E.; Bellato, M.; Bergnoli, Antonio; Birkenfeld, Thilo; Blin, Sylvie; Blum, David; Blyth, S.; Bolshakova, Anastasia; Bongrand, M.; Bordereau, Clément; Bretón, D.; Brigatti, A.; Brugnera, R.; Bruno, Riccardo; Budano, A.; Buscemi, Mario; Busto, J.; Butorov, Ilya; Cabrera, A.; Cai, H.; X, Cai; Cai, Yanke; Cai, Zhiyan; Callegari, Riccardo; Cammi, Antonio; Campeny, Agustín; Cao, Chuanya; Cao, G. F.; Cao, Jian; Caruso, R.; Cerna, C.; Chang, J. F.; Chang, Yun Sil; Chen, Pingping; Chen, Po–An; Chen, Shaomin; Chen, Xurong; Chen, Yiwen; Chen, Yixue; Chen, Yu; Chen, Zhang; Cheng, Jie; Cheng, Ying-Sheng; Chetverikov, Alexey; Chiesa, D.; Chimenti, P.; Chukanov, A.; Claverie, Gérard; Clementi, Catia; Clerbaux, B.; Lorenzo, Selma Conforti Di; Corti, Daniele; Corso, F. Dal; Dalager, Olivia; Taille, C. De La; Deng, J.; Zhi, Deng; Deng, Z. Y.; Depnering, Wilfried; Díaz, M. A.; Ding, Xuefeng; Ding, Yayun; Dirgantara, Bayu; Dmitrievsky, Sergey; Dohnal, Tadeáš; Dolzhikov, Dmitry; Donchenko, Georgy; Dong, Jianmeng; Doroshkevich, E.; Dracos, M.; Druillole, F.; Du, Ruxu; Du, S. X.; Dusini, S.; Dvořák, Martin; Enqvist, T.; Enzmann, Heike; Fabbri, Andrea; Fajt, L.; Fan, Donghua; Li, Fan; Fang, J.; Fang, W.; Fargetta, Marco; Fedoseev, Dmitry; Fekete, V.; Feng, Li‐Cheng; Feng, Qichun; Ford, R.; Fournier, Amélie; Gan, Haonan; Gao, Feng; Garfagnini, A.; Gavrikov, Arsenii; Giammarchi, M.; Giaz, A.; Giudice, Nunzio; Gonchar, M.; Gong, Guanghua; Gong, Haimei; Gornushkin, Y.; Göttel, Alexandre; Grassi, M.; Grewing, Christian; Gromov, Vasily; Gu, M. H.; Gu, Xiaofei; Gu, Yu; Guan, Mengyun; Guardone, Nunzio; Gul, M.; Cong, Gao; Guo, Jun; Guo, Wanlei; Guo, Xin-Heng; Guo, Yuhang; Hackspacher, Paul; Hagner, C.; Han, Ran; Han, Yu; Hassan, Muhammad Sohaib; He, Miao; Wang, He; Heinz, Tobias; Hellmuth, Patrick; Heng, Y. K.; Herrera, R. S.; Hor, YuenKeung; Hou, Shaojing; Hsiung, Y.; Hu, Bei-Zhen; Sun, Luyi; Hu, Jianrun; Hu, Jun; Hu, Shouyang; Hu, T.; Hu, Zhuojun; Huang, Chun-Hao P.; Huang, Guihong; Huang, Hanxiong; Huang, Wenhao; Huang, Xin; Huang, X. T.; Huang, Yuguang; Hui, Jiaqi; Huo, Lei; Huo, Wenju; Huss, Cédric; Hussain, Safeer; Ioannisian, Ara; Isocrate, R.; Jelmini, Beatrice; Jen, K. L.; Jeria, Ignacio; Ji, X. L.; Ji, X. L.; Jia, Huihui; Jia, J.; Jian, Siyu; Jiang, Di; Jiang, Wei; Jiang, X. S.; Jin, Ruyi; Jing, Xiaoping; Jollet, C.; Joutsenvaara, Jari; Jungthawan, Sirichok; Kalousis, Leonidas; Kampmann, Philipp; Li, Kang; Karaparambil, Rebin; Kazarian, Narine; Khosonthongkee, K.; Korablëv, D.; Kouzakov, Konstantin; Krasnoperov, A.; Kruth, A.; Kutovskiy, Nikolay; Kuusiniemi, P.; Lachenmaier, T.; Landini, Cecilia; Leblanc, Sébastien; Lebrin, Victor; Lefèvre, Frédéric; Lei, Ruiting; Leitner, R.; Leung, Jason; Li, Demin; Li, Fēi; 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; Liang, H.; Liebau, Daniel; Limphirat, A.; Limpijumnong, Sukit; Lin, Guey-Lin; Lin, Shu; Lin, Tong; Ling, Jiajie; Lippi, I.; Liu, 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; Lokhov, Alexey; Lombardi, P.; Lombardo, Claudio; Loo, Kai; Lü, Chuan; Lu, Haoqi; Lu, Jingbin; Lu, J. D.; Lu, Shengyong; Liu, Xiaoxu; Лубсандоржиев, Б.; Lubsandorzhiev, Sultim; Ludhová, L.; Lukanov, Arslan; Luo, Fengjiao; Luo, Guangheng; Luo, P. W.; Luo, Sheng; Luo, W.; Lyashuk, V. I.; Ma, Bangzheng; Ma, Qiumei; Ma, Songde; Ma, Xiaoyan; Ma, Xubo; Maalmi, Jihane; Malyshkin, Yury; Mandujano, R. C.; Mantovani, Fabio; Manzali, Francesco; Mao, Xin; Mao, Y.; Mari, Stefano Maria; Marini, F.; Marium, Sadia; Martellini, Cristina; Martin-Chassard, Gisèle; Martini, A.; Mayer, Mathias; Mayilyan, Davit; Mednieks, Ints; Meng, Yue; Meregaglia, A.; Meroni, E.; Meyhöfer, David; Mezzetto, M.; Miller, J.; Miramonti, L.; Montini, P.; Montuschi, M.; Müller, Axel H. E.; Nastasi, M.; Naumov, D.; Naumova, Elena N.; Navas-Nicolás, D.; Nemchenok, I.; Thi, Minh Thuan Nguyen; Ning, Feipeng; Ning, Z.; Nunokawa, Hiroshi; Oberauer, L.; Ochoa-Ricoux, J. P.; Olshevskiy, A.; Orestano, D.; Ortica, F.; Othegraven, Rainer; Pan, Hsiao-Ru; Paoloni, A.; Parmeggiano, S.; Pei, Yatian; Pelliccia, N.; Peng, Anguo; Peng, H.; Perrot, F.; Petitjean, Pierre-Alexandre; Petrucci, F.; Pilarczyk, Oliver; Rico, Luis Felipe Piñeres; Popov, A.; Poussot, Pascal; Pratumwan, Wathan; Previtali, E.; Qi, F. Z.; Qi, M.; Qian, S.; Qian, Xiaohui; Zhang, Qian; Qiao, Hao; Qin, Z. H.; Qiu, Shoukang; Rajput, Muhammad Usman; Ranucci, G.; Raper, N.; Re, A.; Rebber, Henning; Rebii, Abdel; Ren, Bin; Ren, Jie; Ricci, B.; Robens, Markus; Roche, Mathieu; Rodphai, Narongkiat; Romani, Annalisa; Roskovec, B.; Roth, Christian; Ruan, X. D.; Ruan, Xichao; Rujirawat, Saroj; Рыбников, А.; Sadovsky, A.; Saggese, Paolo; Sanfilippo, Simone; Sangka, Anut; Sanguansak, Nuanwan; Sawangwit, U.; Sawatzki, Julia; Sawy, Fatma; Schever, Michaela; Schwab, Cédric; Schweizer, Konstantin; Selyunin, A.; Serafini, Andrea; Settanta, Giulio; Settimo, M.; Shao, Zhuang; Sharov, Vladislav; Shaydurova, Arina; Shi, J. Y.; Shi, Yue; Shutov, Vitaly; Sidorenkov, A.; Šimkovic, F.; Sirignano, C.; Siripak, Jaruchit; Sisti, M.; Słupecki, M.; Smirnov, M. B.; Smirnov, O.; Sogo-Bezerra, Thiago; Соколов, С. В.; Songwadhana, Julanan; Soonthornthum, Boonrucksar; Sotnikov, A.; Šrámek, Ondřej; Sreethawong, Warintorn; Stahl, A.; Stančo, L.; Stankevich, Konstantin; Štefánik, Dušan; Steiger, Hans Jakob; Steinmann, J.; Sterr, Tobias; Stock, Matthias Raphael; Strati, Virginia; Studenikin, Alexander; Sun, Shaobo; Sun, Xilei; Sun, Yueming; Sun, Y. Z.; Suwonjandee, N.; Szelezniak, Michal; Tang, J.; Tang, Qiang; Tang, Quan; Tang, X.; Tietzsch, Alexander; Tkachev, I.; Tměj, Tomáš; Torri, Marco Danilo Claudio; Treskov, Konstantin; Triossi, A.; Troni, Giancarlo; Trzaska, W. H.; Tuvé, C.; Ушаков, Н.; Boom, Johannes van den; Waasen, Stefan van; Vanroyen, Guillaume; Vedin, Vadim; Verde, G.; Vialkov, Maxim; Viaud, B.; Vollbrecht, Moritz; Volpe, Cristina; Vorobel, V.; Воронин, Д.; Votano, L.; Walker, Pablo; Wang, Caishen; Wang, Chung-Hsiang; Wang, En; Wang, Guoli; Wang, Jian; 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; Waqas, M.; Watcharangkool, Apimook; Wei, Lianghong; Wei, Wei; Wei, Wenlu; Wei, Yadong; Wen, Kejun; Wen, L.; Wiebusch, C. H.; Wong, Steven Chan-Fai; Wonsak, Bjoern; Wu, Diru; Wu, Qun; Wang, Zhi; Wurm, M.; Wurtz, Jacques; Wysotzki, Christian; Xi, Yufei; Xia, Dongmei; Xie, Xiaochuan; Xie, Y.; Xie, Z.; Zhang, Xing; Xu, Benda; Chen, Xu; Xu, D. L.; Fang, Xu; Xu, Hangkun; Xu, Jilei; Xu, Jing; Xu, M.; Yin, Xiaoxing; Xu, Yu; Yan, Bin; Yan, Taylor; Wu, Yan; Yan, Xiongbo; Yan, Yupeng; Yang, Anbo; Yang, Changgen; Yang, Chengfeng; Yang, Huan; Yang, Jie; Yang, Liu; Yang, Xiaoyu; Yang, Yifan; Yao, Haifeng; Yasin, Z.; Ye, Jiaxuan; Ye, Mei; Ye, Ziping; Yegin, Ugur; Yermia, F.; Yi, Peihuai; Yin, Ning; Yin, Xiangwei; Zhou, You; Yu, Bo; Yu, Chiye; Yu, C. X.; Yu, Hongzhao; Yu, Miao; Yu, Xianghui; Yu, Zeyuan; Yu, Zezhong; Yuan, C. Z.; Ying, Yibin; Yuan, Zhenxiong; Zhang, Yuan; Yue, Baobiao; Zafar, Noman; Zambanini, André; Zavadskyi, Vitalii; Zeng, Shan; Zeng, Tingxuan; Zeng, Yuda; Zhan, Li; Zhang, Aiqiang; Zhang, Feiyang; Zhang, Guoqing; Zhang, Haiqiong; Zhang, Honghao; Zhang, Jiawen; Zhang, Jie; Zhang, Jin; 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; Zhao, Fengyi; Zhao, Jie; Zhao, Ran; Zhao, S. J.; Zhao, T. C.; Zheng, Dongqin; Zheng, Hairong; Zheng, Minshan; Zheng, Y.; Zhong, Wei; Zhou, Jing; Li, Zhou; Zhou, Nan; Zhou, Shun; Zhou, Tong; Zhang, Xiang; Zhu, Jiang; Zhu, Kangfu; Zhu, K.; Zhu, Zhihong; Zhuang, B. A.; Zhuang, H. L.; Zong, Liang; Zou, J. H.

doi:10.1007/jhep06(2022)062

Cited by 10 publications

(9 citation statements)

References 79 publications

(158 reference statements)

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“…(1.1) by an order of magnitude. The JUNO collaboration itself, following the analysis of [6], has studied the expected sensitivity of their experiment to various mechanisms of damping of neutrino oscillations, including damping due to neutrino WP separation [4]. They concluded that JUNO should be able to set the limits σ p /p < 1.04 × 10 −2 and σ x > 2.3 × 10 −10 cm, both at 95% C.L.…”

Section: Jhep11(2022)082mentioning

confidence: 99%

“…The fragments quickly thermalize on the time scale that is many orders of magnitude shorter than their lifetimes τ N with respect to β-decay. 4 Therefore, at the moment of the decay the parent nuclei are in thermal equilibrium with the medium, and their velocities are determined by the temperature of the medium T . For a fragment of mass m N the average velocity is…”

Section: Neutrino Wps In the Case Of Delocalized Accompanying Particlesmentioning

confidence: 99%

“…In a number of papers the possibility of probing quantum decoherence effects due to the separation of the WPs of different neutrino mass eigenstates composing an emitted flavour-state neutrino was discussed. In particular, possible manifestations of neutrino WP separation in reactor experiments [1][2][3][4][5] and experiments with radioactive neutrino sources [5] have been investigated (for earlier and related discussions, including those for other neutrino experiments, see e.g. [6][7][8][9][10][11][12][13][14]).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Damping of neutrino oscillations, decoherence and the lengths of neutrino wave packets

Akhmedov

Smirnov

2022

J. High Energ. Phys.

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Spatial separation of the wave packets (WPs) of neutrino mass eigenstates leads to decoherence and damping of neutrino oscillations. Damping can also be caused by finite energy resolution of neutrino detectors or, in the case of experiments with radioactive neutrino sources, by finite width of the emitted neutrino line. We study in detail these two types of damping effects using reactor neutrino experiments and experiments with radioactive 51Cr source as examples. We demonstrate that the effects of decoherence by WP separation can always be incorporated into a modification of the energy resolution function of the detector and so are intimately entangled with it. We estimate for the first time the lengths σx of WPs of reactor neutrinos and neutrinos from a radioactive 51Cr source. The obtained values, σx = (2 × 10−5 − 1.4 × 10−4) cm, are at least six orders of magnitude larger than the currently available experimental lower bounds. We conclude that effects of decoherence by WP separation cannot be probed in reactor and radioactive source experiments.

show abstract

Section: Jhep11(2022)082mentioning

confidence: 99%

Section: Neutrino Wps In the Case Of Delocalized Accompanying Particlesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Damping of neutrino oscillations, decoherence and the lengths of neutrino wave packets

Akhmedov

Smirnov

2022

J. High Energ. Phys.

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“…As for the phenomenology part of neutrino decoherence, roughly speaking, measurements of neutrinos produced in both long and short baseline experiments and in the atmosphere are best fitted with neutrinos considered as fully coherent, see for instance [36] for an updated global fit; as for neutrinos produced outside the Earth, such as solar and supernova neutrinos, it is best described as fully incoherent. There are also many discussions on neutrino decoherence phenomenons, such as general neutrino decoherence for reactor experiments in [37][38][39]; gravitation fluctuation or cosmological effects causing atmospheric neutrino decoherence in [18,[40][41][42]; matter effect responsible for accelerator or atmospheric JHEP08(2022)111 neutrino decoherence in [22,[43][44][45][46]. Our structure carries the potential of including all the mechanisms above and more, since both the QFT approach and the open quantum system concept is included.…”

Section: Jhep08(2022)111mentioning

confidence: 99%

“…This is because it has less uncertainty compared to the Double Chooz experiment and a less complicated structure for the distribution of reactors and detectors compared with the Daya Bay experiment, which would affect the damping signature through σ L in a non-trivial way, see appendix D. In addition, different dependence on L 0 and E 0 in the damping signatures in neutrino oscillation is discussed in e.g. [39,62].…”

Section: Jhep08(2022)111 4 Phenomenology Of Neutrino Decoherencementioning

confidence: 99%

Microscopic and macroscopic effects in the decoherence of neutrino oscillations

Cheng

Lindner

Rodejohann

2022

J. High Energ. Phys.

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We present a generic structure (the layer structure) for decoherence effects in neutrino oscillations, which includes decoherence from quantum mechanical and classical uncertainties. The calculation is done by combining the concept of open quantum system and quantum field theory, forming a structure composed of phase spaces from microscopic to macroscopic level. Having information loss at different levels, quantum mechanical uncertainties parameterize decoherence by an intrinsic mass eigenstate separation effect, while decoherence for classical uncertainties is typically dominated by a statistical averaging effect. With the help of the layer structure, we classify the former as state decoherence (SD) and the latter as phase decoherence (PD), then further conclude that both SD and PD result from phase wash-out effects of different phase structures on different layers. Such effects admit for simple numerical calculations of decoherence for a given width and shape of uncertainties. While our structure is generic, so are the uncertainties, nonetheless, a few notable ones are: the wavepacket size of the external particles, the effective interaction volume at production and detection, the energy reconstruction model and the neutrino production profile. Furthermore, we estimate the experimental sensitivities for SD and PD parameterized by the uncertainty parameters, for reactor neutrinos and decay-at-rest neutrinos, using a traditional rate measuring method and a novel phase measuring method.

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Particle physics using reactor antineutrinos

Akindele,

Bowden,

Roca

et al. 2024

J. Phys. G: Nucl. Part. Phys.

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Nuclear reactors are uniquely powerful, abundant, and flavor-pure sources of antineutrinos that have played a central role in the discovery of the neutrinos and in elucidation of their properties. This continues through a broad range of experiments investigating topics including Standard Model and short-baseline oscillations, BSM physics searches, and reactor flux and spectrum modelling. This Report will survey the state of the reactor antineutrino physics field and summarize the ways in which current and future reactor antineutrino experiments can play a critical role in advancing the field of particle physics in the next decade.

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Damping signatures at JUNO, a medium-baseline reactor neutrino oscillation experiment

Cited by 10 publications

References 79 publications

Damping of neutrino oscillations, decoherence and the lengths of neutrino wave packets

Damping of neutrino oscillations, decoherence and the lengths of neutrino wave packets

Microscopic and macroscopic effects in the decoherence of neutrino oscillations

Particle physics using reactor antineutrinos

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