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Study of the wave packet treatment of neutrino oscillation at Daya Bay

Authors :
An, F. P.
Balantekin, A. B.
Band, H. R.
Bishai, M.
Blyth, S.
Cao, D.
Cao, G. F.
Cao, J.
Cen, W. R.
Chan, Y. L.
Chang, J. F.
Chang, L. C.
Chang, Y.
Chen, H. S.
Chen, Q. Y.
Chen, S. M.
Chen, Y. X.
Chen, Y.
Cheng, J. -H.
Cheng, J.
Cheng, Y. P.
Cheng, Z. K.
Cherwinka, J. J.
Chu, M. C.
Chukanov, A.
Cummings, J. P.
de Arcos, J.
Deng, Z. Y.
Ding, X. F.
Ding, Y. Y.
Diwan, M. V.
Dolgareva, M.
Dove, J.
Dwyer, D. A.
Edwards, W. R.
Gill, R.
Gonchar, M.
Gong, G. H.
Gong, H.
Grassi, M.
Gu, W. Q.
Guan, M. Y.
Guo, L.
Guo, X. H.
Guo, Z.
Hackenburg, R. W.
Han, R.
Hans, S.
He, M.
Heeger, K. M.
Heng, Y. K.
Higuera, A.
Hor, Y. K.
Hsiung, Y. B.
Hu, B. Z.
Hu, T.
Hu, W.
Huang, E. C.
Huang, H. X.
Huang, X. T.
Huber, P.
Huo, W.
Hussain, G.
Jaffe, D. E.
Jaffke, P.
Jen, K. L.
Jetter, S.
Ji, X. P.
Ji, X. L.
Jiao, J. B.
Johnson, R. A.
Joshi, J.
Kang, L.
Kettell, S. H.
Kohn, S.
Kramer, M.
Kwan, K. K.
Kwok, M. W.
Kwok, T.
Langford, T. J.
Lau, K.
Lebanowski, L.
Lee, J.
Lee, J. H. C.
Lei, R. T.
Leitner, R.
Leung, J. K. C.
Li, C.
Li, D. J.
Li, F.
Li, G. S.
Li, Q. J.
Li, S.
Li, S. C.
Li, W. D.
Li, X. N.
Li, Y. F.
Li, Z. B.
Liang, H.
Lin, C. J.
Lin, G. L.
Lin, S.
Lin, S. K.
Lin, Y. -C.
Ling, J. J.
Link, J. M.
Littenberg, L.
Littlejohn, B. R.
Liu, D. W.
Liu, J. L.
Liu, J. C.
Loh, C. W.
Lu, C.
Lu, H. Q.
Lu, J. S.
Luk, K. B.
Lv, Z.
Ma, Q. M.
Ma, X. Y.
Ma, X. B.
Ma, Y. Q.
Malyshkin, Y.
Caicedo, D. A. Martinez
McKeown, R. D.
Mitchell, I.
Mooney, M.
Nakajima, Y.
Napolitano, J.
Naumov, D.
Naumova, E.
Ngai, H. Y.
Ning, Z.
Ochoa-Ricoux, J. P.
Olshevskiy, A.
Pan, H. -R.
Park, J.
Patton, S.
Pec, V.
Peng, J. C.
Pinsky, L.
Pun, C. S. J.
Qi, F. Z.
Qi, M.
Qian, X.
Raper, N.
Ren, J.
Rosero, R.
Roskovec, B.
Ruan, X. C.
Steiner, H.
Sun, G. X.
Sun, J. L.
Tang, W.
Taychenachev, D.
Treskov, K.
Tsang, K. V.
Tull, C. E.
Viaux, N.
Viren, B.
Vorobel, V.
Wang, C. H.
Wang, M.
Wang, N. Y.
Wang, R. G.
Wang, W.
Wang, X.
Wang, Y. F.
Wang, Z.
Wang, Z. M.
Wei, H. Y.
Wen, L. J.
Whisnant, K.
White, C. G.
Whitehead, L.
Wise, T.
Wong, H. L. H.
Wong, S. C. F.
Worcester, E.
Wu, C. -H.
Wu, Q.
Wu, W. J.
Xia, D. M.
Xia, J. K.
Xing, Z. Z.
Xu, J. Y.
Xu, J. L.
Xu, Y.
Xue, T.
Yang, C. G.
Yang, H.
Yang, L.
Yang, M. S.
Yang, M. T.
Ye, M.
Ye, Z.
Yeh, M.
Young, B. L.
Yu, Z. Y.
Zeng, S.
Zhan, L.
Zhang, C.
Zhang, H. H.
Zhang, J. W.
Zhang, Q. M.
Zhang, X. T.
Zhang, Y. M.
Zhang, Y. X.
Zhang, Z. J.
Zhang, Z. Y.
Zhang, Z. P.
Zhao, J.
Zhao, Q. W.
Zhao, Y. B.
Zhong, W. L.
Zhou, L.
Zhou, N.
Zhuang, H. L.
Zou, J. H.
Publication Year :
2016

Abstract

The disappearance of reactor $\bar{\nu}_e$ observed by the Daya Bay experiment is examined in the framework of a model in which the neutrino is described by a wave packet with a relative intrinsic momentum dispersion $\sigma_\text{rel}$. Three pairs of nuclear reactors and eight antineutrino detectors, each with good energy resolution, distributed among three experimental halls, supply a high-statistics sample of $\bar{\nu}_e$ acquired at nine different baselines. This provides a unique platform to test the effects which arise from the wave packet treatment of neutrino oscillation. The modified survival probability formula was used to fit Daya Bay data, providing the first experimental limits: $2.38 \cdot 10^{-17} < \sigma_{\rm rel} < 0.23$. Treating the dimensions of the reactor cores and detectors as constraints, the limits are improved: $10^{-14} \lesssim \sigma_{\rm rel} < 0.23$, and an upper limit of $\sigma_{\rm rel} <0.20$ is obtained. All limits correspond to a 95\% C.L. Furthermore, the effect due to the wave packet nature of neutrino oscillation is found to be insignificant for reactor antineutrinos detected by the Daya Bay experiment thus ensuring an unbiased measurement of the oscillation parameters $\sin^22\theta_{13}$ and $\Delta m^2_{32}$ within the plane wave model.

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.1608.01661
Document Type :
Working Paper