Strangeonium-like hybrids on the lattice

Abstract

The strangeonium-like ssg hybrids are investigated from lattice QCD in the quenched approximation. In the Coulomb gauge, spatially extended operators are constructed for 1-- and (0,1,2)-+ states with the color octet ss component being separated from the chromomagnetic field strength by spatial distances r, whose matrix elements between the vacuum and the corresponding states are interpreted as Bethe-Salpeter (BS) wave functions. In each of the (1,2)-+ channels, the masses and the BS wave functions are reliably derived. The 1-+ ground state mass is around 2.1-2.2 GeV, and that of 2-+ is around 2.3-2.4 GeV, while the masses of the first excited states are roughly 1.4 GeV higher. This mass splitting is much larger than the expectation of the phenomenological flux-tube model or constituent gluon model for hybrids, which is usually a few hundred MeV. The BS wave functions with respect to r show clear radial nodal structures of non-relativistic two-body system, which imply that r is a meaningful dynamical variable for these hybrids and motivate a color halo picture of hybrids that the color octet ss is surrounded by gluonic degrees of freedom. In the 1-- channel, the properties of the lowest two states comply with those of φ(1020) and φ(1680). We have not obtained convincing information relevant to φ(2170) yet, however, we argue that whether φ(2170) is a conventional ss meson or a ssg hybrid within the color halo scenario, the ratio of partial decay widths (φ η) and (φ η') observed by BESIII can be understood by the mechanism of hadronic transition of a strangeonium-like meson along with the η-η' mixing.