Joint neutrino oscillation analysis from the T2K and NOvA experiments

The NOvA Collaboration; The T2K Collaboration

doi:10.1038/s41586-025-09599-3

Joint neutrino oscillation analysis from the T2K and NOvA experiments

The NOvA Collaboration
, The T2K Collaboration

Department of Physics
Erciyes University
Fermi National Accelerator Laboratory
Institute of Physics of the Czech Academy of Sciences
Institute for Nuclear Research of the Russian Academy of Sciences
Long Beach VA and University of California
Wichita State University
University of Cincinnati
University of Pittsburgh
University of Minnesota
Tufts University
Indiana University Bloomington
Syracuse University
Iowa State University
Queen Mary University of London
The Ohio State University
College of William and Mary
University of Houston
Illinois Institute of Technology
Cochin University of Science and Technology
University College London
Charles University
University of South Carolina
National Institute of Science Education and Research
Florida State University
Czech Technical University in Prague
University of Hyderabad
Banaras Hindu University
University of Tokyo
University of Delhi
University of Sussex
Department of Biosciences and Bioengineering
Joint Institute for Nuclear Research, Dubna
Panjab University
University of Wisconsin
California Institute of Technology
Argonne National Laboratory
University of Mississippi
The University of Texas at Austin
University of Minnesota Duluth
University of Virginia
Institute of Computer Science of the Academy of Sciences of the Czech Republic
Universidade Federal de Goiás
Indian Institute of Technology Hyderabad
Universety of South Alabama
Southern Methodist University
Colorado State University
Michigan State University
Bandirma Onyedi Eylul University
Universidad del Atlántico, Colombia
Universidad del Magdalena
King's College London
Sorbonne Université
University of Colorado Boulder
Warsaw University of Technology
Imperial College London
Kobe University
Stony Brook University
ETH Zurich
TRIUMF
University of British Columbia
Institute for Nuclear Physics
National Centre for Nuclear Research (NCBJ)
York University
Kyoto University
University of Oxford
York College/The City University of New York
Osaka City University
Nambu Yoichiro Institute of Theoretical and Experimental Physics (NITEP)
Stanford Linear Accelerator Center
Ernest Orlando Lawrence Berkeley National Laboratory
Johannes Gutenberg University
CCLRC Rutherford Appleton Laboratory
Boston University
The University of Sheffield
Tohoku University
European Organization for Nuclear Research
University of Geneva
Université Paris-Saclay
University of São Paulo
Louisiana State University
High Energy Accelerator Research Organization (KEK)
J-PARC Center
University of Liverpool
RWTH Aachen University
INFN Sezione di Bari
Lancaster University
University of Glasgow
Wroclaw University
Royal Holloway University of London
Okayama University
Tokyo Metropolitan University
Duke University
Tokyo University of Science
University of Pennsylvania School of Arts and Sciences
Institute For Interdisciplinary Research in Science and Education
Vietnam Academy of Science and Technology
University of Padova
University of Warsaw
Ip Paris
Keio University
Ghent University
Hanoi University of Science
University of Toyama
Eötvös Loránd University
Yokohama National University
University of Seville
University of Rochester
Tokyo Institute of Technology
IPSA-DRII
South Dakota School of Mines and Technology
University of Warwick
University of Rome
University of Naples Federico II
University of Silesia
Universidad Autónoma de Madrid
Vietnam Academy of Science and Technology (VAST)
Miyagi University of Education

Research output: Contribution to journal › Article › peer-review

Abstract

The landmark discovery that neutrinos have mass and can change type (or flavour) as they propagate—a process called neutrino oscillation^{1, 2, 3, 4, 5–6}—has opened up a rich array of theoretical and experimental questions being actively pursued today. Neutrino oscillation remains the most powerful experimental tool for addressing many of these questions, including whether neutrinos violate charge-parity (CP) symmetry, which has possible connections to the unexplained preponderance of matter over antimatter in the Universe^{7, 8, 9, 10–11}. Oscillation measurements also probe the mass-squared differences between the different neutrino mass states (Δm²), whether there are two light states and a heavier one (normal ordering) or vice versa (inverted ordering), and the structure of neutrino mass and flavour mixing¹². Here we carry out the first joint analysis of datasets from NOvA¹³ and T2K¹⁴, the two currently operating long-baseline neutrino oscillation experiments (hundreds of kilometres of neutrino travel distance), taking advantage of our complementary experimental designs and setting new constraints on several neutrino sector parameters. This analysis provides new precision on the Δm322 mass difference, finding 2.43−0.03+0.04×10−3eV2 in the normal ordering and −2.48−0.04+0.03×10−3eV2 in the inverted ordering, as well as a 3σ interval on δ_CP of [−1.38π, 0.30π] in the normal ordering and [−0.92π, −0.04π] in the inverted ordering. The data show no strong preference for either mass ordering, but notably, if inverted ordering were assumed true within the three-flavour mixing model, then our results would provide evidence of CP symmetry violation in the lepton sector.

Original language	English
Pages (from-to)	818-824
Number of pages	7
Journal	Nature
Volume	646
Issue number	8086
DOIs	https://doi.org/10.1038/s41586-025-09599-3
Publication status	Published - 23 Oct 2025

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10.1038/s41586-025-09599-3

Cite this

@article{1a978fcd92774126bf3436ed1dc876dd,

title = "Joint neutrino oscillation analysis from the T2K and NOvA experiments",

abstract = "The landmark discovery that neutrinos have mass and can change type (or flavour) as they propagate—a process called neutrino oscillation1, 2, 3, 4, 5–6—has opened up a rich array of theoretical and experimental questions being actively pursued today. Neutrino oscillation remains the most powerful experimental tool for addressing many of these questions, including whether neutrinos violate charge-parity (CP) symmetry, which has possible connections to the unexplained preponderance of matter over antimatter in the Universe7, 8, 9, 10–11. Oscillation measurements also probe the mass-squared differences between the different neutrino mass states (Δm2), whether there are two light states and a heavier one (normal ordering) or vice versa (inverted ordering), and the structure of neutrino mass and flavour mixing12. Here we carry out the first joint analysis of datasets from NOvA13 and T2K14, the two currently operating long-baseline neutrino oscillation experiments (hundreds of kilometres of neutrino travel distance), taking advantage of our complementary experimental designs and setting new constraints on several neutrino sector parameters. This analysis provides new precision on the Δm322 mass difference, finding 2.43−0.03+0.04×10−3eV2 in the normal ordering and −2.48−0.04+0.03×10−3eV2 in the inverted ordering, as well as a 3σ interval on δCP of [−1.38π, 0.30π] in the normal ordering and [−0.92π, −0.04π] in the inverted ordering. The data show no strong preference for either mass ordering, but notably, if inverted ordering were assumed true within the three-flavour mixing model, then our results would provide evidence of CP symmetry violation in the lepton sector.",

author = "\{The NOvA Collaboration\} and \{The T2K Collaboration\} and R. Zwaska and J. Zalesak and S. Zadorozhnyy and K. Yonehara and A. Yankelevich and A. Yahaya and B. Yaeggy and Y. Xiao and W. Wu and S. Wu and J. Wolcott and Wickremasinghe, \{D. A.\} and D. Whittington and M. Wetstein and C. Weber and Warburton, \{T. K.\} and M. Wallbank and Waldron, \{A. V.\} and Vockerodt, \{K. J.\} and Z. Vallari and P. Vahle and J. Urheim and J. Trokan-Tenorio and D. Tran and Y. Torun and M. Titus and E. Tiras and J. Thomas and T. Thakore and P. Tas and N. Talukdar and A. Sztuc and C. Sweeney and S. Swain and A. Sutton and L. Suter and M. Strait and K. Soustruznik and A. Sousa and N. Solomey and P. Snopok and J. Smolik and A. Smith and Singha, \{D. K.\} and \{Singh Chhibra\}, S. and V. Singh and B. Quilain and M. Gonin and O. Drapier and \{Buizza Avanzini\}, M.",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

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day = "23",

doi = "10.1038/s41586-025-09599-3",

language = "English",

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pages = "818--824",

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TY - JOUR

T1 - Joint neutrino oscillation analysis from the T2K and NOvA experiments

AU - The NOvA Collaboration

AU - The T2K Collaboration

AU - Zwaska, R.

AU - Zalesak, J.

AU - Zadorozhnyy, S.

AU - Yonehara, K.

AU - Yankelevich, A.

AU - Yahaya, A.

AU - Yaeggy, B.

AU - Xiao, Y.

AU - Wu, W.

AU - Wu, S.

AU - Wolcott, J.

AU - Wickremasinghe, D. A.

AU - Whittington, D.

AU - Wetstein, M.

AU - Weber, C.

AU - Warburton, T. K.

AU - Wallbank, M.

AU - Waldron, A. V.

AU - Vockerodt, K. J.

AU - Vallari, Z.

AU - Vahle, P.

AU - Urheim, J.

AU - Trokan-Tenorio, J.

AU - Tran, D.

AU - Torun, Y.

AU - Titus, M.

AU - Tiras, E.

AU - Thomas, J.

AU - Thakore, T.

AU - Tas, P.

AU - Talukdar, N.

AU - Sztuc, A.

AU - Sweeney, C.

AU - Swain, S.

AU - Sutton, A.

AU - Suter, L.

AU - Strait, M.

AU - Soustruznik, K.

AU - Sousa, A.

AU - Solomey, N.

AU - Snopok, P.

AU - Smolik, J.

AU - Smith, A.

AU - Singha, D. K.

AU - Singh Chhibra, S.

AU - Singh, V.

AU - Quilain, B.

AU - Gonin, M.

AU - Drapier, O.

AU - Buizza Avanzini, M.

PY - 2025/10/23

Y1 - 2025/10/23

N2 - The landmark discovery that neutrinos have mass and can change type (or flavour) as they propagate—a process called neutrino oscillation1, 2, 3, 4, 5–6—has opened up a rich array of theoretical and experimental questions being actively pursued today. Neutrino oscillation remains the most powerful experimental tool for addressing many of these questions, including whether neutrinos violate charge-parity (CP) symmetry, which has possible connections to the unexplained preponderance of matter over antimatter in the Universe7, 8, 9, 10–11. Oscillation measurements also probe the mass-squared differences between the different neutrino mass states (Δm2), whether there are two light states and a heavier one (normal ordering) or vice versa (inverted ordering), and the structure of neutrino mass and flavour mixing12. Here we carry out the first joint analysis of datasets from NOvA13 and T2K14, the two currently operating long-baseline neutrino oscillation experiments (hundreds of kilometres of neutrino travel distance), taking advantage of our complementary experimental designs and setting new constraints on several neutrino sector parameters. This analysis provides new precision on the Δm322 mass difference, finding 2.43−0.03+0.04×10−3eV2 in the normal ordering and −2.48−0.04+0.03×10−3eV2 in the inverted ordering, as well as a 3σ interval on δCP of [−1.38π, 0.30π] in the normal ordering and [−0.92π, −0.04π] in the inverted ordering. The data show no strong preference for either mass ordering, but notably, if inverted ordering were assumed true within the three-flavour mixing model, then our results would provide evidence of CP symmetry violation in the lepton sector.

AB - The landmark discovery that neutrinos have mass and can change type (or flavour) as they propagate—a process called neutrino oscillation1, 2, 3, 4, 5–6—has opened up a rich array of theoretical and experimental questions being actively pursued today. Neutrino oscillation remains the most powerful experimental tool for addressing many of these questions, including whether neutrinos violate charge-parity (CP) symmetry, which has possible connections to the unexplained preponderance of matter over antimatter in the Universe7, 8, 9, 10–11. Oscillation measurements also probe the mass-squared differences between the different neutrino mass states (Δm2), whether there are two light states and a heavier one (normal ordering) or vice versa (inverted ordering), and the structure of neutrino mass and flavour mixing12. Here we carry out the first joint analysis of datasets from NOvA13 and T2K14, the two currently operating long-baseline neutrino oscillation experiments (hundreds of kilometres of neutrino travel distance), taking advantage of our complementary experimental designs and setting new constraints on several neutrino sector parameters. This analysis provides new precision on the Δm322 mass difference, finding 2.43−0.03+0.04×10−3eV2 in the normal ordering and −2.48−0.04+0.03×10−3eV2 in the inverted ordering, as well as a 3σ interval on δCP of [−1.38π, 0.30π] in the normal ordering and [−0.92π, −0.04π] in the inverted ordering. The data show no strong preference for either mass ordering, but notably, if inverted ordering were assumed true within the three-flavour mixing model, then our results would provide evidence of CP symmetry violation in the lepton sector.

UR - https://www.scopus.com/pages/publications/105019732060

U2 - 10.1038/s41586-025-09599-3

DO - 10.1038/s41586-025-09599-3

M3 - Article

C2 - 41125778

AN - SCOPUS:105019732060

SN - 0028-0836

VL - 646

SP - 818

EP - 824

JO - Nature

JF - Nature

IS - 8086

ER -

Joint neutrino oscillation analysis from the T2K and NOvA experiments

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