Up, down, and strange nucleon axial form factors from lattice QCD

• Main Authors: Green, Jeremy (Author), Hasan, Nesreen (Author), Meinel, Stefan (Author), Engelhardt, Michael (Author), Krieg, Stefan (Author), Laeuchli, Jesse (Author), Orginos, Kostas (Author), Syritsyn, Sergey (Author), Negele, John W (Contributor), Pochinsky, Andrew (Contributor)
• Other Authors: Massachusetts Institute of Technology. Center for Theoretical Physics (Contributor), Massachusetts Institute of Technology. Department of Physics (Contributor), Massachusetts Institute of Technology. Laboratory for Nuclear Science (Contributor)
• Format: Article
• Language: English
• Published: American Physical Society, 2017-06-19T19:22:37Z.
• Subjects: Article
• Online Access: Get fulltext

 We report a calculation of the nucleon axial form factors G[superscript q][superscript A](Q[superscript 2]) and G[superscript q][subscript P](Q[superscript 2]) for all three light quark flavors q ∈ {u,d,s} in the range 0 ≤ Q[superscript 2] ≲ 1.2  GeV[superscript 2] using lattice QCD. This work was done using a single ensemble with pion mass 317 MeV and made use of the hierarchical probing technique to efficiently evaluate the required disconnected loops. We perform nonperturbative renormalization of the axial current, including a nonperturbative treatment of the mixing between light and strange currents due to the singlet-nonsinglet difference caused by the axial anomaly. The form factor shapes are fit using the model-independent z expansion. From G[superscript q][subscript A](Q[superscript 2]), we determine the quark contributions to the nucleon spin and axial radii. By extrapolating the isovector G[superscript u-d][subscript P](Q[superscript 2]), we obtain the induced pseudoscalar coupling relevant for ordinary muon capture and the pion-nucleon coupling constant. We find that the disconnected contributions to G[subscript P] form factors are large, and give an interpretation based on the dominant influence of the pseudoscalar poles in these form factors.