General considerations on the nature of Zb(10610) and Zb(10650) from their pole positions

Abstract

The nature of the bottomonium-like states Zb(10610) and Zb(10650) is studied by calculating the B(*) B* compositeness (X) in those resonances. We first consider uncoupled isovector S-wave scattering of B(*) B* within the framework of effective-range expansion (ERE). Expressions for the scattering length (a) and effective range (r) are derived exclusively in terms of the masses and widths of the two Zb states. We then develop compositeness within ERE for the resonance case and deduce the expression X=1/2r/a-1, which is then applied to the systems of interest. Finally, the actual compositeness parameters are calculated in terms of resonance pole positions and their experimental branching ratios into B(*)B* by using the method of Ref.[1]. We find the values X=0.66 0.11 and 0.51 0.10 for the Zb(10610) and Zb(10650), respectively. We also compare the ERE with Breit-Wigner and Flatt\'e parameterizations to discuss the applicability of the last two ones for near-threshold resonances with explicit examples.