Quasielastic Scattering at MiniBooNE Energies

Alvarez‐Ruso, L.; Buß, O.; Leitner, T.; Mosel, U.

doi:10.1063/1.3274146

Cited by 25 publications

(34 citation statements)

References 24 publications

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“…The measured total cross section is consistent to within 10% (the error on overall normalization) of the expected cross section with M A = 1.35 GeV. Nuclear effects can give a larger effective M A in the Q 2 shape of the data [6] but these effects reduce the total cross section, not enhance it. It may be that the larger measured M A values in both Q 2 shape and reaction rate are a coincidence, but further investigation is warranted.…”

Section: Charged-current Quasielastic Scatteringsupporting

confidence: 54%

SciNOvA: A Measurement of Neutrino-Nucleus Scattering in a Narrow-Band Beam

Tayloe¹

2010

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We propose to construct and deploy a fine-grained detector in the Fermilab NOvA 2 GeV narrow-band neutrino beam. In this beam, the detector can make unique contributions to the measurement of quasi-elastic scattering, neutral-current elastic scattering, neutral-current π 0 production, and enhance the NOvA measurements of electron neutrino appearance. To minimize cost and risks, the proposed detector is a copy of the SciBar detector originally built for the K2K long baseline experiment and used recently in the SciBooNE experiment.

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Section: Charged-current Quasielastic Scatteringsupporting

confidence: 54%

SciNOvA: A Measurement of Neutrino-Nucleus Scattering in a Narrow-Band Beam

Tayloe¹

2010

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“…In all the cases there is a significant deficit of events in the region cos θ μ ∼ 1. These are low Q 2 events for which it is known that techniques going beyond the FG (like RPA or CRPA) should be used [20].…”

Section: Resultsmentioning

confidence: 99%

Transverse enhancement model and MiniBooNE charge current quasi-elastic neutrino scattering data

Sobczyk

2012

Eur. Phys. J. C

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“…π∆ and L (1) πN ∆ are consistent in the sense that they are invariant under the so-called point transformation [57,58], so as to compensate the spurious unphysical components of the Rarita-Schwinger field.…”

Section: B Chiral Effective Lagrangianmentioning

confidence: 99%

“…One of the most important quantities is the nucleon isovector axial form factor. This is not only because its value at zero momentum transfer defines the prominent nucleon axial charge g A , but also due to the relevance of its momentumtransfer dependence to experimental processes such as (quasi)elastic neutrino-nucleon scattering, whose precise understanding is crucial to achieve the precision goals in the determination of neutrino-oscillation parameters [1].…”

Section: Introductionmentioning

confidence: 99%

Extraction of nucleon axial charge and radius from lattice QCD results using baryon chiral perturbation theory

2017

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We calculate the nucleon axial form factor up to the leading one-loop order in a covariant chiral effective field theory with the ∆(1232) resonance as an explicit degree of freedom. We fit the axial form factor to the latest lattice QCD data and pin down the relevant low-energy constants. The lattice QCD data, for various pion masses below 400 MeV, can be well described up to a momentum transfer of ∼ 0.6 GeV. The ∆(1232) loops contribute significantly to this agreement. Furthermore, we extract the axial charge and radius based on the fitted values of the low energy constants. The results are: gA = 1.237(74) and r 2 A = 0.263(38) fm 2 . The obtained coupling gA is consistent with the experimental value if the uncertainty is taken into account. The axial radius is below but in agreement with the recent extraction from neutrino quasi-elastic scattering data on deuterium, which has large error bars. Up to our current working accuracy, rA is predicted only at leading order, i.e., one-loop level. A more precise determination might need terms of O(p 5 ).

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Quasielastic Scattering at MiniBooNE Energies

Cited by 25 publications

References 24 publications

SciNOvA: A Measurement of Neutrino-Nucleus Scattering in a Narrow-Band Beam

SciNOvA: A Measurement of Neutrino-Nucleus Scattering in a Narrow-Band Beam

Transverse enhancement model and MiniBooNE charge current quasi-elastic neutrino scattering data

Extraction of nucleon axial charge and radius from lattice QCD results using baryon chiral perturbation theory

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