Measurement of Final-State Correlations in Neutrino Muon-Proton Mesonless Production on Hydrocarbon at Eν ©=3 GeV

(MINERvA Collaboration)

doi:10.1103/PhysRevLett.121.022504

Measurement of Final-State Correlations in Neutrino Muon-Proton Mesonless Production on Hydrocarbon at Eν ©=3 GeV

(MINERvA Collaboration)

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Abstract

Final-state kinematic imbalances are measured in mesonless production of νμ+A→μ-+p+X in the MINERvA tracker. Initial- and final-state nuclear effects are probed using the direction of the μ - p transverse momentum imbalance and the initial-state momentum of the struck neutron. Differential cross sections are compared to predictions based on current approaches to medium modeling. These models underpredict the cross section at intermediate intranuclear momentum transfers that generally exceed the Fermi momenta. As neutrino interaction models need to correctly incorporate the effect of the nucleus in order to predict neutrino energy resolution in oscillation experiments, this result points to a region of phase space where additional cross section strength is needed in current models, and demonstrates a new technique that would be suitable for use in fine-grained liquid argon detectors where the effect of the nucleus may be even larger.

Original language	English (US)
Article number	022504
Journal	Physical review letters
Volume	121
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.121.022504
State	Published - Jul 11 2018

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© 2018 authors. Published by the American Physical Society.

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@article{49420c9ce93b41c8b69f8e0a9c075896,

title = "Measurement of Final-State Correlations in Neutrino Muon-Proton Mesonless Production on Hydrocarbon at Eν {\textcopyright}=3 GeV",

abstract = "Final-state kinematic imbalances are measured in mesonless production of νμ+A→μ-+p+X in the MINERvA tracker. Initial- and final-state nuclear effects are probed using the direction of the μ - p transverse momentum imbalance and the initial-state momentum of the struck neutron. Differential cross sections are compared to predictions based on current approaches to medium modeling. These models underpredict the cross section at intermediate intranuclear momentum transfers that generally exceed the Fermi momenta. As neutrino interaction models need to correctly incorporate the effect of the nucleus in order to predict neutrino energy resolution in oscillation experiments, this result points to a region of phase space where additional cross section strength is needed in current models, and demonstrates a new technique that would be suitable for use in fine-grained liquid argon detectors where the effect of the nucleus may be even larger.",

author = "{(MINERvA Collaboration)} and Lu, {X. G.} and M. Betancourt and T. Walton and F. Akbar and L. Aliaga and O. Altinok and Andrade, {D. A.} and M. Ascencio and L. Bellantoni and A. Bercellie and A. Bodek and A. Bravar and H. Budd and T. Cai and Carneiro, {M. F.} and J. Chaves and D. Coplowe and {Da Motta}, H. and Dytman, {S. A.} and D{\'i}az, {G. A.} and J. Felix and L. Fields and R. Fine and Gago, {A. M.} and R. Galindo and H. Gallagher and A. Ghosh and Gran, {Richard W} and S. Henry and S. Jena and D. Jena and J. Kleykamp and M. Kordosky and T. Le and E. Maher and S. Manly and Mann, {W. A.} and Marshall, {C. M.} and McFarland, {K. S.} and McGowan, {A. M.} and B. Messerly and J. Miller and Mislivec, {Aaron R} and J. Mousseau and D. Naples and Nelson, {J. K.} and C. Nguyen and A. Norrick",

note = "Publisher Copyright: {\textcopyright} 2018 authors. Published by the American Physical Society.",

year = "2018",

month = jul,

day = "11",

doi = "10.1103/PhysRevLett.121.022504",

language = "English (US)",

volume = "121",

journal = "Physical review letters",

issn = "0031-9007",

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TY - JOUR

T1 - Measurement of Final-State Correlations in Neutrino Muon-Proton Mesonless Production on Hydrocarbon at Eν ©=3 GeV

AU - (MINERvA Collaboration)

AU - Lu, X. G.

AU - Betancourt, M.

AU - Walton, T.

AU - Akbar, F.

AU - Aliaga, L.

AU - Altinok, O.

AU - Andrade, D. A.

AU - Ascencio, M.

AU - Bellantoni, L.

AU - Bercellie, A.

AU - Bodek, A.

AU - Bravar, A.

AU - Budd, H.

AU - Cai, T.

AU - Carneiro, M. F.

AU - Chaves, J.

AU - Coplowe, D.

AU - Da Motta, H.

AU - Dytman, S. A.

AU - Díaz, G. A.

AU - Felix, J.

AU - Fields, L.

AU - Fine, R.

AU - Gago, A. M.

AU - Galindo, R.

AU - Gallagher, H.

AU - Ghosh, A.

AU - Gran, Richard W

AU - Henry, S.

AU - Jena, S.

AU - Jena, D.

AU - Kleykamp, J.

AU - Kordosky, M.

AU - Le, T.

AU - Maher, E.

AU - Manly, S.

AU - Mann, W. A.

AU - Marshall, C. M.

AU - McFarland, K. S.

AU - McGowan, A. M.

AU - Messerly, B.

AU - Miller, J.

AU - Mislivec, Aaron R

AU - Mousseau, J.

AU - Naples, D.

AU - Nelson, J. K.

AU - Nguyen, C.

AU - Norrick, A.

PY - 2018/7/11

Y1 - 2018/7/11

N2 - Final-state kinematic imbalances are measured in mesonless production of νμ+A→μ-+p+X in the MINERvA tracker. Initial- and final-state nuclear effects are probed using the direction of the μ - p transverse momentum imbalance and the initial-state momentum of the struck neutron. Differential cross sections are compared to predictions based on current approaches to medium modeling. These models underpredict the cross section at intermediate intranuclear momentum transfers that generally exceed the Fermi momenta. As neutrino interaction models need to correctly incorporate the effect of the nucleus in order to predict neutrino energy resolution in oscillation experiments, this result points to a region of phase space where additional cross section strength is needed in current models, and demonstrates a new technique that would be suitable for use in fine-grained liquid argon detectors where the effect of the nucleus may be even larger.

AB - Final-state kinematic imbalances are measured in mesonless production of νμ+A→μ-+p+X in the MINERvA tracker. Initial- and final-state nuclear effects are probed using the direction of the μ - p transverse momentum imbalance and the initial-state momentum of the struck neutron. Differential cross sections are compared to predictions based on current approaches to medium modeling. These models underpredict the cross section at intermediate intranuclear momentum transfers that generally exceed the Fermi momenta. As neutrino interaction models need to correctly incorporate the effect of the nucleus in order to predict neutrino energy resolution in oscillation experiments, this result points to a region of phase space where additional cross section strength is needed in current models, and demonstrates a new technique that would be suitable for use in fine-grained liquid argon detectors where the effect of the nucleus may be even larger.

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U2 - 10.1103/PhysRevLett.121.022504

DO - 10.1103/PhysRevLett.121.022504

M3 - Article

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SN - 0031-9007

VL - 121

JO - Physical review letters

JF - Physical review letters

IS - 2

M1 - 022504

ER -

Measurement of Final-State Correlations in Neutrino Muon-Proton Mesonless Production on Hydrocarbon at Eν ©=3 GeV

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