Weak Neutral Current Axial Form Factor Using ()-Nucleon Scattering and Lattice QCD Inputs

Abstract

We present a determination of the neutral current weak axial charge GZA(0)=-0.654(3) stat(5) sys using the strange quark axial charge GsA(0) calculated with lattice QCD. We then perform a phenomenological analysis, where we combine the strange quark electromagnetic form factor from lattice QCD with (anti)neutrino-nucleon scattering differential cross section from MiniBooNE experiments in a momentum transfer region 0.24 Q2 0.71 GeV2 to determine the neutral current weak axial form factor GZA(Q2) in the range of 0 Q2≤ 1 GeV2. This yields a phenomenological value of GZA(0)=-0.687(89) stat(40) sys. The value of GZA(0) constrained by the lattice QCD calculation of GsA(0), when compared to its phenomenological determination, provides a significant improvement in precision and accuracy and can be used to provide a constraint on the fit to GZA(Q2) for Q2>0. This constrained fit leads to an unambiguous determination of (anti)neutrino-nucleon neutral current elastic scattering differential cross section near Q2=0 and can play an important role in numerically isolating nuclear effects in this region. We show a consistent description of GZA(Q2) obtained from the (anti)neutrino-nucleon scattering cross section data requires a nonzero contribution of the strange quark electromagnetic form factor. We demonstrate the robustness of our analysis by providing a post-diction of the BNL E734 experimental data.