P-wave charmonium contribution to hidden-charm states from reanalysis of lattice QCD data

Abstract

We reanalyze, considering the contribution of P-wave charmonia, lattice data for the D D-DsDs coupled-channel of S. Prelovsek et al. [JHEP 06, 035 (2021)] and DD* systems of S. Prelovsek et al. [Phys. Rev. Lett. 111, 192001 (2013)] with mπ 280 and 266 MeV, and L=24a/32a (a 0.09 fm) and L=16a (a0.1239(13) fm), respectively. The hidden-charm states with JPC=0++, 1++, and 2++ quantum numbers are then searched for. For 0++, the analysis reveals three poles in the DD-DsDs coupled-channel amplitude, corresponding to three states. Two of these poles, located near the DD and DsDs thresholds, can be interpreted as mostly molecular states. A third pole above the DsDs threshold is originated from the P-wave c0(2P) charmonium state. The number of poles found in the D D-Ds Ds system is the same as that found in the original lattice analysis though the position of the third pole changes sizeably. In the 1++ sector, we find two poles in the complex energy plane. The first one is related to the molecular X(3872) state, with a compositeness exceeding 90\%, while the second one, stemming from the c1(2P) charmonium, appears above the DD* threshold and it likely corresponds to the recently discovered c1(4010) state. In the 2++ sector, we also report two poles and find that the dressed c2(2P) is lighter than the D*D* molecular state, with the dynamics of the latter closely related to that of the heavy-quark spin-symmetry partner of the X(3872). Our exploratory study of the 1++ and 2++ sectors offers valuable insights into their dynamics, but given that the fits that we carry out are underconstrained, more lattice data are required to draw robust conclusions.

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