Strong decays of $P_ψ^N(4440)^+$ and $P_ψ^N(4457)^+$ within the Bethe-Salpeter framework (2503.08440v1)

Abstract: By combining the effective Lagrangian and Bethe-Salpeter framework, we studied the mass spectra, wave functions, and strong decay widths of the two pentaquark states $P_\psi^N(4440)^+$ and $P_\psi^N(4457)^+$ reported by LHCb in 2019. We calculate the one-boson-exchange interaction kernel of $\bar D^*\Sigma_c$ in the isospin-$\frac12$ configuration. Then we present the Bethe-Salpeter equation(BSE) and wave functions for the bound states of a vector meson and a $\frac12$ baryon with $J^P={\frac12}^-$ and ${\frac32}^-$. By solving the BSE we obtain 2 bound states for both ${\frac12}^-$ and ${\frac32}^-$ spin-parity configuration, and the mass results favor the $(\frac32)^-$ and $(\frac12)^-$ configuration for the $P_\psi^N(4440)$ and $P_\psi^N(4457)$. Combining the effective Lagrangians and the obtained BS wave functions, we further calculate the strong decay channels $\bar D^{(*)0}\Lambda_c^+$, $J/\psi(\eta_c) p$, and $\bar D\Sigma_c^{(*)}$ for the two $P_\psi^N$ states. In the favored $\frac32^-$ and $\frac12^-$ configuration, the obtained total widths are 34.8 MeV and $2.2$ MeV for $P_\psi^N(4440)$ and $P_\psi^N(4457)$, respectively, which are substantially consistent with the LHCb data. The obtained decay widths suggest that $\bar D^{*0}\Lambda_c^+$ and $\bar D\Sigma_c$ are the dominant decay channels to detect $P_\psi^N(4440)$ and $P_\psi^N(4457)$. Taking into account both the mass spectra and decay widths, our results favor the interpretation of $P_\psi^N(4440)$ and $P_\psi^N(4457)$ as the isospin-$\frac12$ $[\bar D^*\Sigma_c]$ molecular states with $J^P$ configuration $(\frac{3}{2})^-$ and $(\frac12)^-$ respectively.