Systematic study of Z+c family from quark model's perspective

Abstract

Inspired by the present experimental status of charged charmonium-like states Zc+, the tetraquark states [cu][cd] are systematically studied in a color flux-tube model with a multi-body confinement potential. The investigation indicates that charged charmonium-like states Zc+(3900) or Zc+(3885), Zc+(3930), Zc+(4020) or Zc+(4025), Z1+(4050), Z2+(4250), and Zc+(4200) can be uniformly described as tetraquark states [cu][cd] with the quantum numbers n2S+1LJ and JP of 13S1 and 1+, 23S1 and 1+, 15S2 and 2+, 13P1 and 1-, 15D1 and 1+, and 13D1 and 1+, respectively. The predicted lowest charged tetraquark state [cu][cd] with 0+ and 11S0 has a energy of 378010 MeV in the model. The tetraquark states are compact three-dimensional spatial configurations similar to a rugby ball, the higher orbital angular momentum L between the diquark [cu] and antidiquark [cd], the more prolate of the states. The multibody color flux-tube, a collective degree of freedom, plays an important role in the formation of those charge tetraquark states. However, the two heavier charged states Z+c(4430) and Z+c(4475) can not be explained as tetraquark states [cu][cd] in this model approach.