Coupled-channel study of the three-body DDK and D*D*K

Abstract

We investigate the three-body DDK system with quantum numbers I(JP) = 12(0-) within a coupled-channel framework that incorporates both DDK and D*D*K configurations. The D(*)D(*) interactions are described using the one-boson-exchange model constrained by the heavy-quark symmetry and fitted to the pole positions of X(3872), Tcc+, and Zc(3900). The D(*)K interaction is from the chiral effective theory, motivated by the molecular interpretation of Ds0*(2317), and is further constrained by lattice-QCD results for the DK scattering lengths. The resulting three-body problem is solved using the Gaussian expansion method, while the complex scaling method is employed to search for possible resonant states. We find that coupled-channel effects from D*D*K are negligible, and the DDK system supports a deeply bound state across a wide range of parameters. Depending on the long-range behavior of the DK interaction, an additional shallow state may emerge near the particle-dimer (D-DK) threshold. The deeply bound state exhibits a compact three-body structure, whereas the shallow state displays characteristic features of a three-body halo configuration. No clear resonance poles are identified within the explored parameter region. Similar results are obtained for the D*D*K system. These findings may provide new insight into few-body dynamics in systems involving charmed mesons and kaons.