Bi-Local Baryon Interpolating Fields with Three Flavours

TL;DR

This paper extends the analysis of baryon interpolating fields to three light flavors, explicitly constructing all necessary chiral multiplets and showing bi-local fields suffice for phenomenological modeling without higher Fock components.

Contribution

It provides a complete construction of three-flavor baryon chiral multiplets using bi-local fields, demonstrating their sufficiency for chiral mixing phenomenology.

Findings

Constructed all three necessary chiral SU(3) multiplets.

Showed bi-local fields are sufficient for phenomenological fits.

No need for higher Fock components in baryon chiral mixing.

Abstract

Fierz identities follow from permutations of quark indices and thus determine which chiral multiplets of baryon fields are Pauli-allowed, and which are not. In a previous paper we have investigated the Fierz identities of baryon fields with two light flavours and found that all bilocal fields that can be constructed from three quarks are Pauli-allowed. That does not mean that all possible chiral multiplets exist, however: some chiral multiplets do not appear among structures with a given spin in the local limit, say J = 1/2. One such chiral multiplet is the [(6,3)+(3,6)], which is necessary for a successful chiral mixing phenomenology. In the present paper we extend those methods to three light flavors, i.e. to SU_F(3) symmetry and explicitly construct all three necessary chiral SU_L(3)*SU_R(3) multiplets, viz. [(6,3)+(3,6)], [(3,3_bar)+(3_bar,3)] and [(3_bar,3)+(3,3_bar)] that are necessary for a phenomenologically successful chiral mixing. We complete this analysis by considering some bi-local baryon fields that are sufficient for the construction of the "missing" spin 1/2 baryon interpolating fields. Bi-local baryon fields have definite total angular momentum only in the local limit. The physical significance of these results lies in the fact that they show that there is no need for higher Fock space components, such as the (q^4 q_bar), in the baryon chiral mixing framework, for the purpose of fitting the observed axial couplings and magnetic moments: all of the sufficient "mirror components" exist as bi-local fields.