Exploring two-body strong decay properties for possible single charm molecular pentaquarks with strangeness $|S|=1,2$

TL;DR

This study systematically analyzes the two-body strong decay properties of single-charm molecular pentaquarks with strangeness, providing predictions for decay widths and patterns to aid experimental identification.

Contribution

It introduces a comprehensive effective Lagrangian approach combined with hadronic molecular wave functions to predict decay behaviors of strange charm pentaquarks, highlighting their distinctive decay signatures.

Findings

Decay widths range from <1 MeV to several tens of MeV.

Decay patterns are dominated by light meson exchange, especially pions.

Branching ratios are stable against variations in binding energy.

Abstract

The exploration of exotic hadrons provides a crucial testing ground for quantum chromodynamics in its non-perturbative regime. In this work, we perform a systematic study of the two-body strong decay properties of single-charm molecular pentaquarks in the $Y_c\bar{K}^{(*)}$ systems, where $Y_c = \Lambda_c$, $\Sigma_c$, $\Xi_c$, and $\Xi_c'$. Employing an effective Lagrangian approach combined with hadronic molecular wave functions derived from the one-boson-exchange model, we compute the decay widths and branching ratios for a series of predicted states with strangeness $|S| = 1$ and $|S| = 2$. Our calculations reveal distinctive decay patterns that serve as fingerprints for molecular identification. The total decay widths vary dramatically, from less than 1 MeV for the narrow $\Sigma_c\bar{K}$ $(I(J^P)=1/2(1/2^-))$ state to several tens of MeV for broader coupled-channel molecules like $\Lambda_c\bar{K}^*/\Sigma_c\bar{K}^*$. A key finding is the stability of the predicted branching ratios against variations in the binding energy. The decay dynamics are dominated by light meson (particularly pion) exchange, leading to a strong preference for final states containing a charmed baryon and a strange meson. Furthermore, coupled-channel effects and isospin-related interference play essential roles in both the formation and decay mechanisms of specific candidates. The results provide concrete, testable predictions for future experimental searches at facilities such as LHCb and Belle II.