-baryon axialvector and pseudoscalar form factors, and associated PCAC relations

Abstract

A quark+diquark Faddeev equation treatment of the baryon bound state problem in Poincar\'e-invariant quantum field theory is used to deliver parameter-free predictions for all six -baryon elastic weak form factors. Amongst the results, it is worth highlighting that there are two distinct classes of such -baryon form factors, (g1, g3, Gπ), (h1, h3, Hπ), the functions within each of which are separately linked via partial conservation of axial current (PCAC) and Goldberger-Treiman (GT) relations. Respectively within each class, the listed form factors possess qualitatively the same structural features as the nucleon axial, induced pseudoscalar, and pion-nucleon coupling form factors. For instance, the -baryon g1 axial form factor can reliably be approximated by a dipole function, characterised by an axial charge gA^+=0.71(9) and mass-scale mA=0.95(2)m. Moreover, the two distinct -baryon PCAC form factor relations are satisfied to a high degree of accuracy on a large range of Q2; the associated GT relations present good approximations only on Q2/m2 0; and pion pole dominance approximations are reliable within both classes. There are two π couplings: gπ = 10.46(1.88); hπ= 35.73(3.75); and the associated form factors are soft. Such couplings commonly arise in phenomenology, which may therefore benefit from our analyses. A flavour decomposition of the axial charges reveals that quarks carry 71\% of the -baryon spin. The analogous result for the proton is ≈ 65\%.