Investigating triply heavy tetraquark states through QCD sum rules

TL;DR

This paper uses QCD sum rules to predict the masses of triply heavy tetraquark states with specific quark compositions, providing theoretical guidance for future experimental searches.

Contribution

It introduces a novel application of QCD sum rules with an energy scale formula to estimate masses of triply heavy tetraquark states, extending previous studies.

Findings

Triply charm tetraquarks have masses 5.38-5.84 GeV and 5.66-6.16 GeV.

Triply bottom tetraquarks have masses 14.89-15.55 GeV and 14.95-15.66 GeV.

Results aid in experimental identification of these states.

Abstract

We apply the method of QCD sum rules to study the \(QQ\bar{Q}\bar{q}\) and \(QQ\bar{Q}\bar{s}\) tetraquark states, where $Q=c,b$ and $q=u,d$, with the quantum number \(J^P = 0^{+}\). We consider the contributions of vacuum condensates up to dimension-9 in the operator product expansion, and use the energy scale formula \(\mu = \sqrt{M_{X}^2 - (i\mathbb{M}_c + j\mathbb{M}_b)^2} - k\mathbb{M}_s\) to determine the optimal energy scales for the QCD spectral densities. Our results indicate that triply charm tetraquark states \(cc\bar{c}\bar{q}\) and \(cc\bar{c}\bar{s}\) have masses in the ranges of $5.38-5.84\,\text{GeV}$ and $5.66-6.16\,\text{GeV}$, respectively. In the bottom sector, triply bottom tetraquark states \(bb\bar{b}\bar{q}\) and \(bb\bar{b}\bar{s}\) have masses in the ranges of $14.89-15.55\,\text{GeV}$ and $14.95-15.66\,\text{GeV}$, respectively. This study could help distinguish these states in upcoming high-energy nuclear and particle experiments.