# $\bar{B}^{(\ast)} \bar{B}^{(\ast)}$ interactions in chiral effective   field theory

**Authors:** Bo Wang, Zhan-Wei Liu, Xiang Liu

arXiv: 1812.04457 · 2019-02-18

## TL;DR

This paper investigates the interactions of double-beauty meson systems using chiral effective field theory, calculating potentials up to one-loop order, and predicts possible bound states relevant for future experiments.

## Contribution

It provides a detailed chiral effective field theory analysis of double-beauty meson interactions, including one-loop corrections and predictions of bound states.

## Key findings

- Attractive potentials in specific channels lead to bound states.
- Predicted binding energies are approximately -12.6 MeV and -23.8 MeV.
- Results aid future experimental searches and lattice QCD extrapolations.

## Abstract

In this work, the intermeson interactions of double-beauty $\bar{B}\bar{B}$, $\bar{B}\bar{B}^\ast$, and $\bar{B}^\ast\bar{B}^\ast$ systems have been studied with heavy meson chiral effective field theory. The effective potentials are calculated with Weinberg's scheme up to one-loop level. At the leading order, four body contact interactions and one pion exchange contributions are considered. In addition to two pion exchange diagrams, we include the one-loop chiral corrections to contact terms and one pion exchange diagrams at the next-to-leading order. The behaviours of effective potentials both in momentum space and coordinate space are investigated and discussed extensively. We notice the contact terms play important roles in determining the characteristics of the total potentials. Only the potentials in $I(J^P)=0(1^+)$ $\bar{B}\bar{B}^\ast$ and $\bar{B}^\ast\bar{B}^\ast$ systems are attractive, and the corresponding binding energies in these two channels are solved to be $\Delta E_{\bar{B}\bar{B}^\ast}\simeq -12.6^{+9.2}_{-12.9}$ MeV and $\Delta E_{\bar{B}^\ast\bar{B}^\ast}\simeq -23.8^{+16.3}_{-21.5}$ MeV, respectively. The masses of $0(1^+)$ $\bar{B}\bar{B}^\ast$ and $\bar{B}^\ast\bar{B}^\ast$ states lie above the threshold of their electromagnetic decay modes $\bar{B}\bar{B}\gamma$ and $\bar{B}\bar{B}\gamma\gamma$, and thus they can be reconstructable via electromagnetic interactions. Our calculation not only provides some useful information to explore exotic doubly-bottomed molecular states for future experiments, but also is helpful for the extrapolations of Lattice QCD simulations.

## Full text

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## Figures

33 figures with captions in the complete paper: https://tomesphere.com/paper/1812.04457/full.md

## References

109 references — full list in the complete paper: https://tomesphere.com/paper/1812.04457/full.md

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Source: https://tomesphere.com/paper/1812.04457