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New charged resonance Z_(c)⁻(4100): the spectroscopic parameters and width

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arxiv 1812.10094 v3 pith:VVHSX3XE submitted 2018-12-25 hep-ph hep-exhep-lat

New charged resonance Z_(c)⁻(4100): the spectroscopic parameters and width

classification hep-ph hep-exhep-lat
keywords couplingmassresonancewidthcalculatedchargedmathrmobtained
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The mass, coupling and width of the newly observed charged resonance $ Z_{c}^{-}(4100)$ are calculated by treating it as a scalar four-quark system with a diquark-antidiquark structure. The mass and coupling of the state $ Z_{c}^{-}(4100)$ are calculated using the QCD two-point sum rules. In these calculations we take into account contributions of the quark, gluon and mixed condensates up to dimension ten. The spectroscopic parameters of $ Z_{c}^{-}(4100)$ obtained by this way are employed to study its $S$-wave decays to $\eta_c(1S)\pi^{-}$, $\eta_c(2S)\pi^{-}$, $D^{0}D^{-}$, and $ J/\psi \rho ^{-}$ final states. To this end, we evaluate the strong coupling constants corresponding to the vertices $Z_{c}\eta_c(1S)\pi^{-}$, $ Z_{c}\eta_c(2S)\pi^{-}$, $Z_{c}D^{0}D^{-}$, and $Z_{c}J/\psi \rho^{-}$ respectively. The couplings $g_{Z_c\eta_{c1} \pi}$, $g_{Z_{c}\eta_{c2} \pi}$ , and $g_{Z_{c}DD}$ are computed by means of the QCD three-point sum rule method, whereas $g_{Z_{c}J/\psi \rho }$ is obtained from the QCD light-cone sum rule approach and soft-meson approximation. Our results for the mass $ m=(4080 \pm 150)~\mathrm{MeV}$ and total width $\Gamma =(147 \pm 19)~\mathrm{ MeV}$ of the resonance $Z_{c}^{-}(4100)$ are in excellent agreement with the existing LHCb data.

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