On extraction of value of axial mass from MiniBooNE neutrino
  quasi-elastic double differential cross section data

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Abstract

MiniBooNE charge current quasi-elastic double differential cross section data are analyzed and confronted with predictions of two theoretical nucleus models: Fermi gas and spectral function. The fitting procedure includes the overall flux uncertainty multiplicative factor. In order to obtain a reliable value of the axial mass, bins with large contribution from small momentum transfer are eliminated from the analysis. It is shown that the best fit axial mass value becomes smaller as the momentum transfer cut is more restrictive. For \(q_{cut}=500\)~MeV/c the obtained values of axial mass are \(M_A=1350\pm 66\)~MeV for the Fermi gas and \(M_A=1343\pm 60\)~MeV for the spectral function. The value \(M_A=1030\)~MeV is excluded on the level which goes far beyond \(5\sigma\).

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Is Open Access

Electron- and neutrino-nucleus scattering in the impulse approximation regime

Makoto Sakuda, Ryoichi Seki, Omar Benhar … (2005)

A quantitative understanding of the weak nuclear response is a prerequisite for the analyses of neutrino experiments such as K2K and MiniBOONE, which measure energy and angle of the muons produced in neutrino-nucleus interactions in the energy range \(0.5-3\) GeV and reconstruct the incident neutrino energy to determine neutrino oscillations. In this paper we discuss theoretical calculations of electron- and neutrino-nucleus scattering, carried out within the impulse approximation scheme using realistic nuclear spectral functions.Comparison between electron scattering data and the calculated inclusive cross section off oxygen, at beam energies ranging between 700 and 1200 MeV, show that the Fermi gas model, widely used in the analysis of neutrino oscillation experiments,fails to provide a satisfactory description of the measured cross sections,and inclusion of nuclear dynamics is needed.