Mass Spectra of Full-Heavy and Double-Heavy Tetraquark States in the Conventional Quark Model
Abstract
A comprehensive study of the S-wave heavy tetraquark states with identical quarks and antiquarks, specifically QQ Q' Q' (Q, Q'=c,b), QQ s s/ Q Q ss, and QQ q q/ Q Q qq (q=u,d), are studied in a unified constituent quark model. This model contains the one-gluon exchange and confinement potentials. The latter is modeled as the sum of all two-body linear potentials. We employ the Gaussian expansion method to solve the full four-body Schr\"odinger equations, and search bound and resonant states using the complex-scaling method. We then identify 3 bound and 62 resonant states. The bound states are all QQ q q states with the isospin and spin-parity quantum numbers I(JP)=0(1+): two bound bbqq states with the binding energies, 153 MeV and 4 MeV below the BB* threshold, and a shallow ccqq state at -15 MeV from the DD* threshold. The deeper bb q q bound state aligns with the lattice QCD predictions, while cc q q bound state, still has a much larger binding energy than the recently observed T+cc by LHCb collaboration. No bound states are identified for the QQ Q' Q', QQ s s and QQ q q with I=1. Our analysis shows that the bound QQ Q' Q' states are more probable with a larger mass ratio, mQ/mQ'. Experimental investigation for these states is desired, which will enrich our understanding of hadron spectroscopy and probe insights into the confinement mechanisms within tetraquarks.
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