Charged-current non-standard neutrino interactions at Daya Bay

Author:

,An F. P.,Bai W. D.ORCID,Balantekin A. B.,Bishai M.,Blyth S.,Cao G. F.,Cao J.,Chang J. F.,Chang Y.,Chen H. S.,Chen H. Y.,Chen S. M.,Chen Y.,Chen Y. X.,Chen Z. Y.,Cheng J.,Cheng Y.-C.,Cheng Z. K.,Cherwinka J. J.,Chu M. C.,Cummings J. P.,Dalager O.,Deng F. S.,Ding X. Y.,Ding Y. Y.,Diwan M. V.,Dohnal T.,Dolzhikov D.,Dove J.,Dugas K. V.,Duyang H. Y.,Dwyer D. A.,Gallo J. P.,Gonchar M.,Gong G. H.,Gong H.,Gu W. Q.,Guo J. Y.,Guo L.,Guo X. H.,Guo Y. H.,Guo Z.,Hackenburg R. W.,Han Y.,Hans S.,He M.,Heeger K. M.,Heng Y. K.,Hor Y. K.,Hsiung Y. B.,Hu B. Z.,Hu J. R.,Hu T.,Hu Z. J.,Huang H. X.,Huang J. H.,Huang X. T.,Huang Y. B.,Huber P.,Jaffe D. E.,Jen K. L.,Ji X. L.,Ji X. P.,Johnson R. A.,Jones D.,Kang L.,Kettell S. H.,Kohn S.,Kramer M.,Langford T. J.,Lee J.,Lee J. H. C.,Lei R. T.,Leitner R.,Leung J. K. C.,Li F.,Li H. L.,Li J. J.,Li Q. J.,Li R. H.,Li S.,Li S.,Li S. C.,Li W. D.,Li X. N.,Li X. Q.,Li Y. F.,Li Z. B.,Liang H.,Lin C. J.,Lin G. L.,Lin S.,Ling J. J.ORCID,Link J. M.,Littenberg L.,Littlejohn B. R.,Liu J. C.,Liu J. L.,Liu J. X.,Lu C.,Lu H. Q.,Luk K. B.,Ma B. Z.,Ma X. B.,Ma X. Y.,Ma Y. Q.,Mandujano R. C.,Marshall C.,McDonald K. T.,McKeown R. D.,Meng Y.,Napolitano J.,Naumov D.,Naumova E.,Nguyen T. M. T.,Ochoa-Ricoux J. P.,Olshevskiy A.,Park J.,Patton S.,Peng J. C.,Pun C. S. J.,Qi F. Z.,Qi M.,Qian X.,Raper N.,Ren J.,Morales Reveco C.,Rosero R.,Roskovec B.,Ruan X. C.,Russell B.,Steiner H.,Sun J. L.,Tmej T.,Tse W.-H.,Tull C. E.,Tung Y. C.,Viren B.,Vorobel V.,Wang C. H.,Wang J.,Wang M.,Wang N. Y.,Wang R. G.,Wang W.,Wang X.,Wang Y. F.,Wang Z.,Wang Z.,Wang Z. M.,Wei H. Y.,Wei L. H.,Wei W.,Wen L. J.,Whisnant K.,White C. G.,Wong H. L. H.,Worcester E.,Wu D. R.,Wu Q.,Wu W. J.,Xia D. M.,Xie Z. Q.,Xing Z. Z.,Xu H. K.,Xu J. L.,Xu T.,Xue T.,Yang C. G.,Yang L.,Yang Y. Z.,Yao H. F.,Ye M.,Yeh M.,Young B. L.,Yu H. Z.,Yu Z. Y.,Yue B. B.,Zavadskyi V.,Zeng S.,Zeng Y.,Zhan L.,Zhang C.,Zhang F. Y.,Zhang H. H.,Zhang J. L.,Zhang J. W.,Zhang Q. M.,Zhang S. Q.,Zhang X. T.,Zhang Y. M.,Zhang Y. X.,Zhang Y. Y.,Zhang Z. J.,Zhang Z. P.,Zhang Z. Y.,Zhao J.,Zhao R. Z.,Zhou L.,Zhuang H. L.,Zou J. H.

Abstract

Abstract The full data set of the Daya Bay reactor neutrino experiment is used to probe the effect of the charged current non-standard interactions (CC-NSI) on neutrino oscillation experiments. Two different approaches are applied and constraints on the corresponding CC-NSI parameters are obtained with the neutrino flux taken from the Huber-Mueller model with a 5% uncertainty. For the quantum mechanics-based approach (QM-NSI), the constraints on the CC-NSI parameters ϵ and $$ {\epsilon}_{e\alpha}^s $$ ϵ s are extracted with and without the assumption that the effects of the new physics are the same in the production and detection processes, respectively. The approach based on the weak effective field theory (WEFT-NSI) deals with four types of CC-NSI represented by the parameters [εX]. For both approaches, the results for the CC-NSI parameters are shown for cases with various fixed values of the CC-NSI and the Dirac CP-violating phases, and when they are allowed to vary freely. We find that constraints on the QM-NSI parameters ϵ and $$ {\epsilon}_{e\alpha}^s $$ ϵ s from the Daya Bay experiment alone can reach the order $$ \mathcal{O} $$ O (0.01) for the former and $$ \mathcal{O} $$ O (0.1) for the latter, while for WEFT-NSI parameters [εX], we obtain $$ \mathcal{O} $$ O (0.1) for both cases.

Publisher

Springer Science and Business Media LLC

Reference54 articles.

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