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Understanding spin parity of $P_c(4450)$ and $Y(4274)$ in a hadronic molecular state picture

arXiv:1607.03223 · doi:10.1103/PhysRevD.95.074004

Abstract

The hidden-charmed pentaquark $P_c(4450)$ and the charmonium-like state $Y(4274)$ are investigated as a $\bar{D}^*Σ_c$ and a $D_s\bar{D}_{s0}(2317)$ molecular state, respectively. The spin parities of these two states cannot be well understood if only S-wave $\bar{D}^*Σ_c$ and $D_s\bar{D}_{s0}(2317)$ interactions are considered. In this work, the interactions are studied in a quasipotential Bethe-Salpeter equation approach with a partial wave decomposition on spin parity $J^P$, and the contributions of different partial waves are studied in a two-channel scattering model including a generating channel and an observation channel. Two poles at $4447\pm4i$ and $4392\pm46i$ MeV are produced from the $\bar{D}^*Σ_c$ interaction coupled with the $J/ψp$ channel in $3/2^-$ wave and $5/2^+$ wave, respectively. The peak for the $5/2^+$ state has a comparable height as that of the $3/2^-$ state in the $J/ψp$ invariant mass spectrum. The $D_s\bar{D}_{s0}(2317)$ interaction coupled with the $J/ψϕ$ channel is studied and a pole at $4275\pm11i$ MeV is produced in $J^{P}=1^{+}$ wave, which corresponds to P-wave $D_s\bar{D}_{s0}(2317)$ interaction. The pole from S-wave $D_s\bar{D}_{s0}(2317)$ interaction is far below that from P-wave interaction even the $J/ψϕ$ threshold, so cannot be observed in the $J/ψϕ$ channel. The result suggests that in these cases a state carrying a spin parity corresponding to P-wave interaction should be taken as seriously as these carrying a spin parity corresponding to S-wave interaction in the hadronic molecular state picture.

7 pages, 5 figures. published version