The newly observed $\Upsilon(10753)$ as a tetraquark state in a chiral quark model with scalar nonet exchange

TL;DR

This paper investigates the nature of the newly observed $3$ resonance, proposing it as a tetraquark state using a chiral quark model and numerical methods, and finds a candidate resonance consistent with experimental data.

Contribution

The study introduces a comprehensive tetraquark model analysis of $3$, including molecular and diquark-antidiquark configurations, identifying a stable resonance that matches experimental observations.

Findings

Identifies a stable tetraquark resonance $^1R_{1}(10770)$ matching $3$ mass and width.

Rules out $5S$ meson as the $3$ candidate.

Predicts additional resonances between 10.82 GeV and 10.96 GeV.

Abstract

Recently, Belle\uppercase\expandafter{\romannumeral2} Collaboration firstly reported a new resonance $\omega\chi_{bJ}$ in the processes of $e^{+}e^{-} \rightarrow \omega\chi_{bJ}$ at center-of-mass energies $\sqrt{s}=10.745$ GeV. Given the Born cross section similar with the previously reported $\Upsilon(10753)$, the new resonance $\omega\chi_{bJ}$ may have be $\Upsilon(10753)$. From the perspectives of traditional $\Upsilon(nS)$ meson and exotic tetraquark $b\bar{q}q\bar{b}$ state with the $J^{PC}$ = $1^{--}$, we tentatively investigate the $\Upsilon(10753)$ by solving Schr\"odinger equation in the framework of the chiral quark model. Numerical results for the meson show that the mass of $\Upsilon(5S)$ is up to 10.86 GeV and unsuitable for the candidate of $\Upsilon(10753)$. On the other hand, not only the two kinds of molecular structure ($b\bar{b}$-$q\bar{q}$, $b\bar{q}$-$q\bar{b}$) but also the \da~structure ($\bar{b}\bar{q}$-$qb$) are considered into our tetraquark calculation with the help of Gaussian expansion method. When a fully-channel coupling is performed using the real-scaling method (stabilization method), we get a stable resonance $^1R_{1}(10770)$ ( $^{2S+1}R_J$ ) with a great component of the diquark-antidiquark state. Combined with the mass and width of $^1R_{1}(10770)$, it may be a good candidate for experimental $\Upsilon(10753)$. Besides, several resonance states ranging from 10.82 GeV to 10.96 GeV are obtained, which are expected to be further verified in future experiments.