Interpretation of (11020) as an S-Wave B1B--B1B* Molecular State

Abstract

Although heavy-quark symmetry predicts a B1B molecular partner of the D1D molecule, no such state has been observed. We propose that the experimentally observed (11020) may be a candidate for such a state, possibly containing a B1B* component. To test this, we interpret (11020) as an S-wave B1B--B1B* molecule and compute its strong decay widths using the compositeness condition and effective Lagrangians. The couplings to B1 and B(*) are extracted by fitting (11020) e+ e- and (11020) bJ πππ data. Using these couplings, we evaluate partial widths into B(*)(s)B(*)(s), ππ (nS), ππ hb(nP), and πππ b1 via hadronic loops, as well as three-body B*π B(*) decays via tree diagrams. The results indicate that (11020) is predominantly a B1B molecule, with its main decay channel being Bs*B*. The ππ (nS) and ππ hb(nP) widths are only a few eV, whereas πππ b1 reaches 0.167~MeV and the unobserved πππ b0 could be 0.754~keV. These distinctive decay patterns provide clear experimental signatures of the molecular nature of (11020) and offer a test of heavy-quark symmetry.