The possible $K^{*}\Sigma^{*}$ molecular state
Abstract
Within the framework of the one-boson-exchange model, we systematically investigate the interaction between the vector meson and the baryon with the aim of exploring the possibility of forming hadronic molecular states. The interaction potential is constructed from , , and meson exchanges, and the nonrelativistic Schr\"odinger equation is solved using the Gaussian expansion method. The binding energies are calculated for different total angular momenta and isospin channels and . Our results show that -- wave mixed molecular states with can be formed only in the channel, while no bound state appears in the channel due to destructive interference of the interaction potentials in isospin space. In addition, the -- wave mixed states with and are also found to support bound-state solutions. For higher partial-wave states, the binding mechanism is governed by the interplay of partial-wave mixing, tensor forces, and spin--orbit interactions. In particular, the channel does not support a bound state because the meson-exchange interaction is predominantly repulsive. Our analysis further supports the interpretation of the experimentally observed and states as molecular states, corresponding to and , respectively.
Cite
@article{arxiv.2604.22359,
title = {The possible $K^{*}\Sigma^{*}$ molecular state},
author = {Yin Huang and Dan Jiang and Feng Zhang and Bo Nan Zhang},
journal= {arXiv preprint arXiv:2604.22359},
year = {2026}
}