Trilepton and tetralepton bound and resonant states: the QED counterpart of multiquark states

TL;DR

This paper predicts and analyzes the existence of tetralepton resonant states containing muons within a QED framework, employing advanced computational methods to identify bound and resonant states and their properties.

Contribution

It provides the first theoretical prediction of muon-containing tetralepton resonant states and explores their characteristics using the Gaussian expansion and complex scaling methods.

Findings

Identified bound and resonant states in various trilepton and tetralepton systems.

Calculated energies, widths, and spatial structures of these states.

Compared QED states with QCD tetraquark systems, highlighting differences in bound state formation.

Abstract

This work presents the first prediction of tetralepton resonant states containing muons, extending beyond the simplest tetralepton system, dipositronium ($\mathrm{Ps}_2$). With the rapid advancements in experimental facilities, the production and study of these intriguing states may be within reach. We perform a comprehensive analysis of S-wave trilepton and tetralepton systems within the framework of a QED Coulomb potential. We employ the Gaussian expansion method to solve the three- or four-body Schr\"odinger equation and utilize the complex scaling method to identify resonant states. We uncover a series of bound and resonant states in the trilepton systems $e^+e^+e^-$, $\mu^+\mu^+\mu^-$, $e^+e^+\mu^-$, and $\mu^+\mu^+e^-$, as well as the tetralepton systems $e^+e^+e^-e^-$, $\mu^+\mu^+\mu^-\mu^-$, and $\mu^+\mu^+e^-e^-$. The energies of these states range from $-30$ eV to $-1$ eV below the total mass of three or four leptons, with their widths varying from less than $0.01$ eV to approximately $0.07$ eV. Additionally, we calculate the spin configurations and root mean square radii of these states, providing insight into their spatial structures. No bound or resonant states are found in the trilepton $e^+\mu^+e^-$, $\mu^+e^+\mu^-$ systems, nor in the tetralepton $\mu^+e^+\mu^-e^-$ system. A comparison with fully heavy tetraquark systems reveals that the additional color degree of freedom in QCD results in the absence of low-energy bound and resonant states. However, this extra degree of freedom allows for a broader range of $J^{PC}$ quantum numbers to produce resonant states, highlighting the rich complexity of QCD systems.