Systematic Study of Coupled-Channel Dynamics in Doubly Heavy Hadronic Molecules

Abstract

Heavy Quark Spin Symmetry (HQSS) is widely use to predict heavy molecules by extending the effective interactions fitted from low-lying states to heavier sectors. In this work, we systematically investigate the reliability of this approach for higher double heavy tetraquarks by comparing a single-channel effective interaction (Scheme I) with an explicit coupled-channel dynamics framework (Scheme II). The interactions are obtained within one-boson-exchange potential model and fixed by fitting the Tcc+ lineshape. Utilizing the complex scaling method and T-matrix pole analysis, we extract the possible poles in the S-wave D(*)D(*), B(*)B(*) and D(*)B(*) systems with JP=1+. We find that both schemes provide consistent descriptions of the lowest-lying state. This confirms isoscalar-dominated Tcc as a predominant DD* molecule (binding energy 381 keV), and predicts an isoscalar deeply bound Tbb state (40-60 MeV) and an isovector Tbb resonance in the bottom sector, together with a virtual Tbc state. In contrast, significant differences emerge for higher-lying states. The inclusion of explicit coupled-channel dynamics modifies the effective interaction and reshapes the pole structure. The states predicted as bound or resonant in the single-channel framework can be shifted far from the physical region or disappear. These results indicate that while single-channel descriptions are adequate for near-threshold states, an explicit treatment of coupled-channel dynamics is required for reliable predictions of excited doubly heavy tetraquarks.