Abstract
In the present work, we investigate the ${\ensuremath{\eta}}_{c}K$, $J/\ensuremath{\psi}K$, ${\ensuremath{\eta}}_{c}{K}^{*}$, and $J/\ensuremath{\psi}{K}^{*}$ hidden-charm decay modes for the $c\overline{c}s\overline{u}$ four-quark system in the molecular and compact tetraquark scenarios using the quark-exchange model. Our theoretical results indicate that if the newly observed states ${Z}_{cs}(3985)$ and ${Z}_{cs}(4000)$ are two different states, ${Z}_{cs}(4000)$ may be interpreted as the mixture $\frac{1}{\sqrt{2}}({D}^{0}{D}_{s}^{*\ensuremath{-}}+{D}^{*0}{D}_{s}^{\ensuremath{-}})$, of which the $J/\ensuremath{\psi}K$ partial decay width is about $\mathrm{\ensuremath{\Gamma}}\ensuremath{\sim}2.89\text{ }\text{ }\mathrm{MeV}$, while ${Z}_{cs}(3985)$ may be explained as the mixture $\frac{1}{\sqrt{2}}(\ensuremath{-}{D}^{0}{D}_{s}^{*\ensuremath{-}}+{D}^{*0}{D}_{s}^{\ensuremath{-}})$, of which the $J/\ensuremath{\psi}K$ partial decay width is small to zero. Moreover, if the state ${Z}_{cs}(4000)$ can be explained as the mixed state $\frac{1}{\sqrt{2}}({D}^{0}{D}_{s}^{*\ensuremath{-}}+{D}^{*0}{D}_{s}^{\ensuremath{-}})$, indeed, the partial decay width ratio between $J/\ensuremath{\psi}K$ and ${\ensuremath{\eta}}_{c}{K}^{*}$ is close to unit, which indicates the decay channel ${\ensuremath{\eta}}_{c}{K}^{*}$ may be a ideal channel as well to decode the inner structure of ${Z}_{cs}(4000)$. In addition, the partial decay width for the tensor molecular state $|{D}^{*0}{D}_{s}^{*\ensuremath{-}}{⟩}_{{2}^{+}}$ decaying into $J/\ensuremath{\psi}{K}^{*}$ can reach up to a few MeV, which shows this tensor molecular state has a good potential to be observed in this decay channel.
Highlights
In the last 20 years, there has been an explosion in the observation of hidden-charmed multiquark states [1–6], for example: dozens of charmoniumlike states have been observed since 2003 [7], most of which are good candidates of four-quark states with quark components ccqq (q denotes u or d quark) [1–6]; the LHCb Collaboration reported hidden-charm pentaquark states Pcð4380Þ and Pcð4450Þ in 2015 [8] and updated the data in 2019 [9], which minimally contain four quarks and one antiquark [10]; last year, the LHCb Collaboration observed a narrow structure around 6.9 GeV in the J=ψ-pair invariant mass spectrum [11], which may be good candidates of compact tetraquark state cccc ̄ [12]
The partial decay width for the tensor molecular state jDÃ0DÃs−i2þ decaying into J=ψKÃ can reach up to a few MeV, which shows this tensor molecular state has a good potential to be observed in this decay channel
In the last 20 years, there has been an explosion in the observation of hidden-charmed multiquark states [1–6], for example: dozens of charmoniumlike states have been observed since 2003 [7], most of which are good candidates of four-quark states with quark components ccqq (q denotes u or d quark) [1–6]; the LHCb Collaboration reported hidden-charm pentaquark states Pcð4380Þ and Pcð4450Þ in 2015 [8] and updated the data in 2019 [9], which minimally contain four quarks and one antiquark [10]; last year, the LHCb Collaboration observed a narrow structure around 6.9 GeV in the J=ψ-pair invariant mass spectrum [11], which may be good candidates of compact tetraquark state cccc [12]
Summary
In the last 20 years, there has been an explosion in the observation of hidden-charmed multiquark states [1–6], for example: dozens of charmoniumlike states have been observed since 2003 [7], most of which are good candidates of four-quark states with quark components ccqq (q denotes u or d quark) [1–6]; the LHCb Collaboration reported hidden-charm pentaquark states Pcð4380Þ and Pcð4450Þ in 2015 [8] and updated the data in 2019 [9], which minimally contain four quarks and one antiquark (ccqqq ) [10]; last year, the LHCb Collaboration observed a narrow structure around 6.9 GeV in the J=ψ-pair invariant mass spectrum [11], which may be good candidates of compact tetraquark state cccc ̄ [12]. Its mass and width are measured to be The mass of this state is comparable to that of Zcsð3985Þ observed by BESIII [13], while its width is about 10 times larger than that of Zcsð3985Þ. Whether they are two different states or not, and how to decode their inner structures, are pretty much the agenda for theorists. To clarify whether Zcsð3985Þ and Zcsð4000Þ are two different states and further show light on the inner structures of the two states, it is critical to study the J=ψK decay mode for the DDÃs and DÃDs molecular states.
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