Double-charm and hidden-charm hexaquark states under the complex scaling method

Abstract

We investigate the double-charm and hidden-charm hexaquarks as molecules in the framework of the one-boson-exchange potential model. The multichannel coupling and S-D wave mixing are taken into account carefully. We adopt the complex scaling method to investigate the possible quasibound states, whose widths are from the three-body decay channel ccπ or ccπ. For the double-charm system of I(JP)=1(1+), we obtain a quasibound state, whose width is 0.50 MeV if the binding energy is -14.27 MeV. And the S-wave cc and cc* components give the dominant contributions. For the 1(0+) double-charm hexaquark system, we do not find any pole. We find more poles in the hidden-charm hexaquark system. We obtain one pole as a quasibound state in the IG(JPC)=1+(0--) system, which only has one channel (cc+cc)/2. Its width is 1.72 MeV with a binding energy of -5.37 MeV. But, we do not find any pole for the scalar 1-(0-+) system. For the vector 1-(1-+) system, we find a quasibound state. Its energies, widths and constituents are very similar to those of the 1(1+) double-charm case. In the vector 1+(1--) system, we get two poles -- a quasibound state and a resonance. The quasibound state has a width of 0.6 MeV with a binding energy of -15.37 MeV. For the resonance, its width is 2.72 MeV with an energy of 63.55 MeV relative to the cc threshold. And its partial width from the two-body decay channel (cc-cc)/2 is apparently larger than the partial width from the three-body decay channel ccπ.

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