# Heavy Baryon-Antibaryon Molecules in Effective Field Theory

**Authors:** Jun-Xu Lu, Li-Sheng Geng, Manuel Pavon Valderrama

arXiv: 1706.02588 · 2019-04-30

## TL;DR

This paper develops an effective field theory framework to study heavy baryon-antibaryon bound states, analyzing pion exchange interactions and estimating the likelihood of various heavy baryonium states in different quantum configurations.

## Contribution

It extends EFT methods used for meson-antimeson states to heavy baryon-antibaryon systems, considering heavy quark spin symmetry and pion exchange effects to predict potential bound states.

## Key findings

- Pion exchanges are non-perturbative in some systems, perturbative in others.
- Certain isoscalar and isovector heavy baryon-antibaryon systems are promising bound state candidates.
- Doubly-heavy baryon-antibaryon pairs are also potential bound states.

## Abstract

We discuss the effective field theory description of bound states composed of a heavy baryon and antibaryon. This framework is a variation of the ones already developed for heavy meson-antimeson states to describe the $X(3872)$ or the $Z_c$ and $Z_b$ resonances. We consider the case of heavy baryons for which the light quark pair is in S-wave and we explore how heavy quark spin symmetry constrains the heavy baryon-antibaryon potential. The one pion exchange potential mediates the low energy dynamics of this system. We determine the relative importance of pion exchanges, in particular the tensor force. We find that in general pion exchanges are probably non-perturbative for the $\Sigma_Q \bar{\Sigma}_Q$, $\Sigma_Q^* \bar{\Sigma}_Q$ and $\Sigma_Q^* \bar{\Sigma}_Q^*$ systems, while for the $\Xi_Q' \bar{\Xi}_Q'$, $\Xi_Q^* \bar{\Xi}_Q'$ and $\Xi_Q^* \bar{\Xi}_Q^*$ cases they are perturbative If we assume that the contact-range couplings of the effective field theory are saturated by the exchange of vector mesons, we can estimate for which quantum numbers it is more probable to find a heavy baryonium state. The most probable candidates to form bound states are the isoscalar $\Lambda_Q \bar{\Lambda}_Q$, $\Sigma_Q \bar{\Sigma}_Q$, $\Sigma_Q^* \bar{\Sigma}_Q$ and $\Sigma_Q^* \bar{\Sigma}_Q^*$ and the isovector $\Lambda_Q \bar{\Sigma}_Q$ and $\Lambda_Q \bar{\Sigma}_Q^*$ systems, both in the hidden-charm and hidden-bottom sectors. Their doubly-charmed and -bottom counterparts ($\Lambda_Q {\Lambda}_Q$, $\Lambda_Q {\Sigma}_Q^{(*)}$, $\Sigma_Q^{(*)} {\Sigma}_Q^{(*)}$) are also good candidates for binding.

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1706.02588/full.md

## References

79 references — full list in the complete paper: https://tomesphere.com/paper/1706.02588/full.md

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Source: https://tomesphere.com/paper/1706.02588