Pentaquark molecular states with hidden bottom and double strangeness

TL;DR

This study predicts new pentaquark molecular states with hidden bottom and double strangeness using an extended hidden gauge approach, identifying several narrow-width states with specific spin-parity assignments through coupled channel analysis.

Contribution

It extends the hidden gauge approach to the heavy quark sector to predict novel pentaquark molecular states with specific quantum numbers and decay properties.

Findings

Several molecular states with small decay widths identified.

States with specific J^P quantum numbers assigned.

Poles of these states and their channel couplings evaluated.

Abstract

We investigate the meson-baryon interaction in coupled channels with the quantum numbers of the pentaquarks $P_{bss}$ and $P_{bsss}$. The interaction is derived from an extension of the local hidden gauge approach to the heavy quark sector, which has demonstrated accurate results compared to experiments involving $\Omega_{b}$, $\Xi_{b}$ states, and pentaquarks $P_{c}$ and $P_{cs}$. In our study, we identify several molecular states with small decay widths within the chosen set of coupled channels. The spin-parity ($J^P$) of these states is as follows: $J^P={\frac{1}{2}}^-$ for pseudoscalar-baryon (${\frac{1}{2}}^+$) coupled channels, $J^P={\frac{3}{2}}^-$ for pseudoscalar-baryon (${\frac{3}{2}}^+$) coupled channels, $J^P={\frac{1}{2}}^-$ and ${\frac{3}{2}}^-$ for vector-baryon (${\frac{1}{2}}^+$) coupled channels, and $J^P={\frac{1}{2}}^-$, ${\frac{3}{2}}^-$, ${\frac{5}{2}}^-$ for vector-baryon (${\frac{3}{2}}^+$) coupled channels. We search for the poles of these states and evaluate their couplings to the different channels.