Prediction of the most strange tri-baryon with lattice QCD constrained potentials

Motivated by the existence of two-body hadronic molecules composed of $\Omega\Omega$, $\Omega_{ccc}\Omega_{ccc}$ and $\Omega_{bbb}\Omega_{bbb}$ predicted by lattice QCD simulations, we employ the Gaussian expansion method to study whether three-body systems composed of $\Omega\Omega\Omega$, $\Omega_{ccc}\Omega_{ccc}\Omega_{ccc}$ and $\Omega_{bbb}\Omega_{bbb}\Omega_{bbb}$ can bind with the two-body $^1S_0$ interactions provided by lattice QCD. Our results show that none of the three-body systems binds. On the other hand, we find that supplemented with a synthetic $^5S_2$ potential, the $\Omega\Omega\Omega$ system develops a bound state, for which both the $^1S_0$ and $^5S_2$ interactions play an important role. Our predictions are further corroborated by explicit studies employing the one-boson exchange potentials constrained by the lattice QCD simulations. Our studies support the existence of the $\frac{3}{2}^+$ $\Omega\Omega\Omega$ bound state and the non-existence of the $\frac{3}{2}^+$ $\Omega_{ccc}\Omega_{ccc}\Omega_{ccc}$ and $\Omega_{bbb}\Omega_{bbb}\Omega_{bbb}$ bound states, due to the suppressed $^5S_2$ interactions in heavier systems.
Comment: 5 pages, 2 figures, 4 tables