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Abstract
We study gluonic excitations inside a $B_{c} $ meson in the constituent gluon model, treating a bottom-charm hybrid meson $ c \bar{b} g $ as a three-body system. We obtain the mass spectra for the hybrid mesons with magnetic gluon and electric gluon and see that their lowest states appear above the $ D B $ threshold. Also, we consider the decays of the low-lying states of the hybrid meson into $ DB , \; D^{*} B, DB^{*} $, $ D^{*}B^{*} $, $ D_{s} B_{s} $, and $D_{s} B_{s}^{*} $ mesons, developing an existing model for the strong decays. We estimate their partial decay widths and find that the widths have a heavy dependence on the final meson states. We argue that the accuracy of our model will be tested experimentally when the branching ratios of the decays are measured. Our results suggest that there could be a prospect that the hybrid meson will be discovered as its first excited state rather than its lowest state.
Highlights
We obtain the mass spectra for the hybrid mesons with magnetic gluon and electric gluon and see that their lowest states appear above the DB threshold
It has been argued for a long time that the experimental verification of exotic hadrons will have far-reaching implications for quantum chromodynamics (QCD), not just because it will give the quantum field theory of the strong interaction another credit for the theory’s accuracy, but because it will make QCD researchers search for nonperturbative properties of the theory with renewed enthusiasm
We study a bottom-charm hybrid meson cbg in the constituent gluon model, considering its mass spectra and decays into DðÃÞBðÃÞ mesons and DðsÃÞBðsÃÞ mesons
Summary
It has been argued for a long time that the experimental verification of exotic hadrons will have far-reaching implications for quantum chromodynamics (QCD), not just because it will give the quantum field theory of the strong interaction another credit for the theory’s accuracy, but because it will make QCD researchers search for nonperturbative properties of the theory with renewed enthusiasm. While it is still difficult to experimentally confirm the existence of exotic hadrons, indirect evidence of it has been accumulating gradually. The event has been described as a milestone in exotic hadron research; dozens of exotic hadron candidates have been discovered. It is widely known that ψð4260Þ [2] aka Y (4260) has been a high-profile exotic meson candidate since it was discovered in 2005 [3]. The question on the constituents of ψð4260Þ has been considered from many different angles: a hadrocharmonium [4], a D D1ð2420Þ molecule [5], a tetraquark, a diquark-antidiquark bound
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