T+cc and its partners
Abstract
Inspired by the T+cc signal discovered by the LHCb Collaboration, we systematically investigate the doubly heavy tetraquark states with the molecule configuration [Q1q2][Q3q4] (Q=c and b, q=u, d and s) in a nonrelativistic quark model. The model involves a color screening confinement potential, meson-exchange interactions and one-gluon-exchange interactions. The T+cc state with IJP=01+ is a very loosely bound deuteron-like state with a binding energy around 0.34 MeV and a huge size of 4.32 fm. Both the meson exchange force and the coupled channel effect play a pivotal role. Without the meson exchange force, there does not exist the T+cc molecular state. In strong contrast, the QCD valence bond forms clearly in the T+bb system when we turn off the meson-exchange force, which is very similar to the hydrogen molecule in QED. Moreover, the T+bb becomes a helium-like QCD-atom if we increase the bottom quark mass by a factor of three. Especially, the T+bb states with 01+, T+bc with 00+ and 01+ and the V-spin antisymmetric states T+bbs with 121+, T+bcs with 120+ and 121+ can form a compact, hydrogen molecule-like or deuteron-like bound state with different binding dynamics. The high-spin states T+bc with 02+ and T+bcs with 122+ can decay into D-wave BD and BsD although they are below the thresholds B*D* and B*sD*, respectively. The isospin and V-spin symmetric states are unbound. We also calculate their magnetic moments and axial charges.
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