The Tbc tetraquarks near the BD threshold

Abstract

We study the doubly heavy open-flavor tetraquarks Tbc(0) (JP=0+) and Tbc(1) (JP=1+) in the dynamical diquark model, describing the system as a heavy antidiquark--light diquark pair interacting through the lattice-QCD g+(1S) Born--Oppenheimer potential. Solving the radial Schr\"odinger equation yields M(Tbc(0)) = 7.143--7.158 GeV and M(Tbc(1)) = 7.217--7.222 GeV, with hyperfine splittings of HF 59--79 MeV. The splitting is driven mainly by the mass difference between symmetric and antisymmetric heavy-antidiquark configurations, while the chromomagnetic interaction contributes linearly with ∂HF/∂ b c=2, consistent with heavy-antidiquark spin algebra. The mean separation, r 0.45--0.46 fm, and inverse radius, 1/r-1 0.33--0.34 fm, exhibit weak parameter dependence and support a compact diquark--antidiquark interpretation. Relative to open-flavor thresholds, the scalar state lies essentially at the B D threshold and may appear either as a weakly decaying bound tetraquark or as a narrow near-threshold resonance. In contrast, the axial-vector state is consistently predicted as an S-wave resonance located 23--28 MeV above B* D and about 70 MeV below B D*, implying a line shape strongly influenced by the nearby B* D threshold.