A quark core-gluon model for heavy hybrid baryons

TL;DR

This paper proposes a QCD-inspired model for heavy hybrid baryons, treating them as a two-body system of a quark core and a gluon, to explore their properties and guide experimental searches.

Contribution

It introduces a semirelativistic potential model for heavy hybrid baryons based on a quark core-gluon picture with flux tube confinement and Casimir scaling.

Findings

Model predicts properties of heavy hybrid baryons with $cccg$ and $bbbg$ configurations.

Highlights the importance of mass asymmetry in hybrid baryon formation.

Provides a framework for future studies of light hybrid baryons.

Abstract

Besides the ordinary hadrons, QCD allows the existence of states in which excitations of the gluonic field can play the role of valence particles, either alone in a glueball, or coupled to quarks in a hybrid. So, hybrid baryons, made of three quarks and a gluon, can a priori exist. Till now, there is no experimental evidence for such exotic hadrons but experimental efforts are being made to search for them at CEBAF Large Acceptance Spectrometer. In this work, a hybrid baryon is considered as a two-body system composed of a color octet three-quark core and a gluon, interacting via a QCD-inspired interaction. A semirelativistic potential model is built in which the dominant interaction is a potential simulating the flux tube confinement, and the Casimir scaling is assumed to link interactions between triplet and octet color sources. This picture is similar to the quark-diquark description for baryons. It is chosen in order to take properly into account the helicity of the gluon. Only $cccg$ and $bbbg$ states are considered because the strong mass asymmetry between the quark core and the gluon is expected to favor the formation of the core. As the results for heavy hybrid baryons seem relevant, we consider this paper as a proof of concept which can be extended for the study of light hybrid baryons.