The following MiniBooNE information from the anti-neutrino CCQE cross section paper is made available to
the public:

- ν
_{μ}CCQE data: - MiniBooNE flux
- table of MiniBooNE anti-neutrino mode flux by neutrino species (Figure 1 and Tables XI-XII). Note that, based on the constraints of the in situ measurements, the muon neutrino flux spectrum given here should be scaled by 0.77.
- flux-integrated double-differential
cross section d
^{2}σ / dT_{μ}d(cosθ_{μ}) - on mineral oil (Figures 8-9 and Tables XIII-XVI):
- 1D array of bin boundaries partitioning the muon kinetic energy in GeV (top) and the cosine of the muon scattering angle (bottom)
- 2D array of the value of the double-differential cross section in each bin in units of 10
^{-41}cm^{2}/GeV/proton. The muon kinetic energy increases from left to right, and the cosine of the muon scattering angle decreases from top to bottom (Table XIII) - 2D array of the shape uncertainty of the double-differential cross section in each bin in units of 10
^{-41}cm^{2}/GeV/proton. The total normalization error is 13.0% (Table XIV). - 2D array of the predicted CCQE-like background double-differential cross section in each bin in units of 10
^{-41}cm^{2}/GeV/proton (Table XV) - 2D array of the predicted CC1π
^{-}background double-differential cross section in each bin in units of 10^{-41}cm^{2}/GeV/proton (Table XVI) - on carbon (Tables XIX-XXI):
- 1D array of bin boundaries partitioning the muon kinetic energy in GeV (top) and the cosine of the muon scattering angle (bottom)
- 2D array of the value of the double-differential cross section in each bin in units of 10
^{-41}cm^{2}/GeV/proton. The muon kinetic energy increases from left to right, and the cosine of the muon scattering angle decreases from top to bottom (Table XIX) - 2D array of the shape uncertainty of the double-differential cross section in each bin in units of 10
^{-41}cm^{2}/GeV/proton. The total normalization error is 17.4% (Table XX). - 2D array of the predicted CCQE-like background double-differential cross section in each bin in units of 10
^{-41}cm^{2}/GeV/proton (Table XXI) - flux-integrated single-differential cross section dσ / dQ
^{2}_{QE} - on mineral oil (Figure 12 and Table XVII):
- 1D array of bin boundaries partitioning the reconstructed four momentum transfer, Q
^{2}_{QE}in GeV^{2} - 1D array of the value of the single-differential cross section in each bin in units of cm
^{2}/GeV^{2}/proton - 1D array of the shape uncertainty of the single-differential cross section in each bin in units of cm
^{2}/GeV^{2}/proton. The total normalization error is 13.0%. - 1D array of the predicted CCQE-like background single-differential cross section in each bin in units of cm
^{2}/GeV^{2}/proton - 1D array of the predicted CC1π
^{-}background single-differential cross section in each bin in units of cm^{2}/GeV^{2}/proton - on carbon (Table XXII):
- 1D array of bin boundaries partitioning the reconstructed four momentum transfer, Q
^{2}_{QE}in GeV^{2} - 1D array of the value of the single-differential cross section in each bin in units of cm
^{2}/GeV^{2}/proton - 1D array of the shape uncertainty of the single-differential cross section in each bin in units of cm
^{2}/GeV^{2}/proton. The total normalization error is 17.4%. - 1D array of the predicted CCQE-like background single-differential cross section in each bin in units of cm
^{2}/GeV^{2}/proton - flux-unfolded cross section σ(E
_{ν}) - on mineral oil (Figure 11 and Table XVIII):
- 1D array of bin boundaries partitioning the neutrino energy
- 1D array of the value of the cross section in each bin in units of cm
^{2}/proton - 1D array of the shape uncertainty of the cross section in each bin in units of cm
^{2}/proton. The total normalization error is 13.0%. - 1D array of the total uncertainty of the cross section in each bin in units of cm
^{2}/proton - 1D array of the predicted CCQE-like background cross section in each bin in units of cm
^{2}/proton - 1D array of the predicted CC1π
^{-}background cross section in each bin in units of cm^{2}/proton - on carbon (Figure 13 and Table XXIII):
- 1D array of bin boundaries partitioning the neutrino energy
- 1D array of the value of the cross section in each bin in units of cm
^{2}/proton - 1D array of the shape uncertainty of the cross section in each bin in units of cm
^{2}/proton. The total normalization error is 17.4%. - 1D array of the total uncertainty of the cross section in each bin in units of cm
^{2}/proton - 1D array of the predicted CCQE-like background cross section in each bin in units of cm
^{2}/proton - For clarifications on how to use MiniBooNE public data or for enquiries about additional data not linked from this page, please contact: Joe Grange or Richard Van de Water
- If you are using data linked from this page, please reference the following papers:
- The MiniBooNE collaboration wishes to acknowledge the support of Fermilab, the U.S. Department of Energy, and the U.S. National Science Foundation for the construction, operation, beam delivery, and data analysis of the MiniBooNE experiment