Nucleon axial-vector and pseudoscalar form factors, and PCAC relations

Abstract

We use a continuum quark+diquark approach to the nucleon bound-state problem in relativistic quantum field theory to deliver parameter-free predictions for the nucleon axial and induced pseudoscalar form factors, GA and GP, and unify them with the pseudoscalar form factor G5 or, equivalently, the pion-nucleon form factor Gπ NN. We explain how partial conservation of the axial-vector current and the associated Goldberger-Treiman relation are satisfied once all necessary couplings of the external current to the building blocks of the nucleon are constructed consistently; in particular, we fully resolve the seagull couplings to the diquark-quark vertices associated with the axial-vector and pseudoscalar currents. Among the results we describe, the following are worth highlighting. A dipole form factor defined by an axial charge gA=GA(0)=1.25(3) and a mass-scale MA = 1.23(3) mN, where mN is the nucleon mass, can accurately describe the pointwise behaviour of GA. Concerning GP, we obtain the pseudoscalar charge gp = 8.80(23), and find that the pion pole dominance approach delivers a reliable estimate of the directly computed result. Our computed value of the pion-nucleon coupling constant, gπ NN/mN =14.02(33)/ GeV is consistent with recent precision determinations.