Measurement of Electron Antineutrino Oscillation Amplitude and Frequency   via Neutron Capture on Hydrogen at Daya Bay

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

arXiv:2406.01007·hep-ex·October 11, 2024

Measurement of Electron Antineutrino Oscillation Amplitude and Frequency via Neutron Capture on Hydrogen at Daya Bay

Daya Bay collaboration: F. P. An, W. D. Bai, A. B. Balantekin, M., Bishai, S. Blyth, G. F. Cao, J. Cao, J. F. Chang, Y. Chang, H. S. Chen, H. Y., Chen, S. M. Chen, Y. Chen, Y. X. Chen, Z. Y. Chen, J. Cheng, J. Cheng, Y.-C., Cheng, Z. K. Cheng, J. J. Cherwinka, M. C. Chu

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TL;DR

This paper reports the first measurement of reactor antineutrino oscillation parameters using neutron capture on hydrogen at Daya Bay, achieving improved precision and consistency with previous gadolinium-based results.

Contribution

It introduces a novel measurement method using neutron capture on hydrogen, providing an independent and precise determination of neutrino oscillation parameters.

Findings

01

Measured for with improved precision.

02

Confirmed consistency with previous gadolinium-based measurements.

03

Enhanced understanding of neutrino oscillation parameters.

Abstract

This Letter reports the first measurement of the oscillation amplitude and frequency of reactor antineutrinos at Daya Bay via neutron capture on hydrogen using 1958 days of data. With over 3.6 million signal candidates, an optimized candidate selection, improved treatment of backgrounds and efficiencies, refined energy calibration, and an energy response model for the capture-on-hydrogen sensitive region, the relative $\overline{ν}_{e}$ rates and energy spectra variation among the near and far detectors gives $sin^{2} 2 θ_{13} = 0.075 9_{- 0.0049}^{+ 0.0050}$ and $Δ m_{32}^{2} = (2.7 2_{- 0.15}^{+ 0.14}) \times 1 0^{- 3}$ eV $^{2}$ assuming the normal neutrino mass ordering, and $Δ m_{32}^{2} = (- 2.8 3_{- 0.14}^{+ 0.15}) \times 1 0^{- 3}$ eV $^{2}$ for the inverted neutrino mass ordering. This estimate of $sin^{2} 2 θ_{13}$ is consistent with and essentially independent from the one…

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Taxonomy

TopicsAtmospheric Ozone and Climate · Oceanographic and Atmospheric Processes · Ionosphere and magnetosphere dynamics