Electromagnetic properties of the $ D \bar D^* K$ molecular hexaquark state

TL;DR

This paper calculates the electromagnetic properties, including magnetic and quadrupole moments, of a hypothesized $D ar D^* K$ molecular hexaquark state, providing theoretical predictions to guide future experimental searches.

Contribution

It presents the first estimate of the magnetic and quadrupole moments of the $D ar D^* K$ hexaquark state using light-cone sum rules, based on its proposed molecular structure.

Findings

The magnetic moment is large due to double electric charge.

The quadrupole moment indicates a non-spherical charge distribution.

Results suggest the state is accessible in future experiments.

Abstract

We systematically study the electromagnetic properties of multiquark states. In this study, inspired by the recent series of studies that showed the likely existence of a $ D \bar D^* K$ state, we examine the magnetic moment of $ D \bar D^* K$ hexaquark state in three-meson molecular structure, as well as having isospin and spin-parity quantum numbers $I(J^P) =3/2(1^-)$ via light-cone sum rules. The magnetic moment obtained for the $ D \bar D^* K$ molecular hexaquark state is quite large due to the double electric charge, and its magnitude indicates that it is accessible in future experiments. As a byproduct, the quadrupole moment of the $ D \bar D^* K$ molecular hexaquark state is also extracted. This value indicates a non-spherical charge distribution. The magnetic moments of hadrons contains valuable knowledge on the distributions of charge and magnetization their inside, which can be used to better understand their geometric shape and quark-gluon organizations. The results given in this study constitute an estimate of the magnetic moment of this $D \bar D^* K$ state and should serve as an inspiration to conduct experimental examinations of this state.