DOE PAGES title logo U.S. Department of Energy
Office of Scientific and Technical Information
  1. Measurement of π0 production in ν ¯ μ charged-current interactions in the NOvA near detector

    We present a high-statistics measurement of muon antineutrino-induced charged-current neutral pion production on a hydrocarbon target using the NOvA near detector. The differential cross sections as functions of the momenta and angles of the outgoing pion and muon, the squared four-momentum transfer, and the invariant mass of the hadronic system at an average neutrino energy of 2 GeV are measured and compared with predictions from various neutrino interaction models. The results agree with the GENIE prediction but suggest that other models underestimate the cross section in the Δ(1232) resonance region. These results represent the most precise measurement ofmore » antineutrino-induced neutral pion production to date.« less
  2. Precision Measurement of Neutrino Oscillation Parameters with 10 Years of Data from the NOvA Experiment

    This Letter reports measurements of muon-neutrino disappearance and electron-neutrino appearance and the corresponding antineutrino processes between the two NOvA detectors in the NuMI neutrino beam. These measurements use a dataset with double the neutrino mode beam exposure that was previously analyzed, along with improved simulation and analysis techniques. A joint fit to these samples in the three-flavor paradigm results in the most precise single-experiment constraint on the atmospheric neutrino mass-splitting, $$Δm^2_{32}= 2.431^{+0.036}_{-0.034} (-2.479^{+0.036}_{-0.036}) \times 10^{-3}$$~eV$^2$ if the mass ordering is Normal (Inverted). In both orderings, a region close to maximal mixing with $$\sin^2θ_{23}=0.55_{+0.06}^{-0.02}$$ is preferred. The NOvA data show amore » mild preference for the Normal mass ordering with a Bayes factor of 2.4 (corresponding to 70% of the posterior probability), indicating that the Normal ordering is 2.4 times more probable than the Inverted ordering. When incorporating a 2D $$Δm^2_{32}\textrm{--}\sin^2 2θ_{13}$$ constraint based on Daya Bay data, this preference strengthens to a Bayes factor of 6.6 (87\%).« less
  3. Explanation of the seasonal variation of cosmic multiple muon events observed with the NOvA Near Detector

    The flux of cosmic ray muons at the Earth’s surface exhibits seasonal variations due to changes in the temperature of the atmosphere affecting the production and decay of mesons in the upper atmosphere. Using 1473 live days of data collected by the NuMI Off-axis 𝜈𝑒 Appearance (NOvA) Near Detector during 2018–2022, we studied the seasonal pattern in the multiple-muon event rate. The data confirm an anticorrelation between the multiple-muon event rate and effective atmospheric temperature, consistent across all the years of data. Previous analyses from MINOS and NOvA saw a similar anticorrelation but did not include an explanation. We findmore » that this anticorrelation is driven by altitude–geometry effects as the average muon production height changes with the season. This has been studied with a CORSIKA cosmic ray simulation package by varying atmospheric parameters, and provides an explanation to a longstanding discrepancy between the seasonal phases of single and multiple-muon events.« less
  4. Joint neutrino oscillation analysis from the T2K and NOvA experiments

    The landmark discovery that neutrinos have mass and can change type (or flavour) as they propagate—a process called neutrino oscillation—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. 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 (invertedmore » ordering), and the structure of neutrino mass and flavour mixing. Here we carry out the first joint analysis of datasets from NOvA and T2K, 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 Δ$$m$$$^{2}_{32}$$ mass difference, finding $2.43$$$$^{+0.04}_{–0.03}$$ x 10–3 eV2 in the normal ordering and $–2.48$$$$^{+0.03}_{–0.04}$$ x 10–3 eV2 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.« less

Search for:
All Records
Creator / Author
"Kirezli, B."

Refine by:
Article Type
Availability
Journal
Creator / Author
Publication Date
Research Organization