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2024年10月30日

Magnetic moments of hidden-charm strange pentaquark states

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Feng Gao and Hao-Song Li. Magnetic moments of hidden-charm strange pentaquark states[J]. Chinese Physics C. doi: 10.1088/1674-1137/ac8651
Feng Gao and Hao-Song Li. Magnetic moments of hidden-charm strange pentaquark states[J]. Chinese Physics C.  doi: 10.1088/1674-1137/ac8651 shu
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Magnetic moments of hidden-charm strange pentaquark states

  • 1. School of Physics, Northwest University, Xi'an 710127, China
  • 2. Institute of Modern Physics, Northwest University, Xi'an 710127, China
  • 3. Shaanxi Key Laboratory for theoretical Physics Frontiers, Xi'an 710127, China
  • 4. Peng Huanwu Center for Fundamental Theory, Xi'an 710127, China

Abstract: In this study, the magnetic moments of hidden-charm strange pentaquark states with quantum numbers$ J^P={\dfrac{1}{2}}^{\pm} $, $ {\dfrac{3}{2}}^{\pm} $, $ {\dfrac{5}{2}}^{\pm} $, and $ {\dfrac{7}{2}}^{+} $are calculated in the molecular, diquark-diquark-antiquark, and diquark-triquark models. The numerical results demonstrate that the magnetic moments change for different spin-orbit couplings within the same model and when involving different models with the same angular momentum.

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    I.   INTRODUCTION
    • The quark model is a successful theory that physicists have used to explain the inner structures of mesons and baryons and predict the tetraquark and pentaquark. Over the past decade, significant theoretical and experimental progress has been made in the exploration of multiquark states, with several exotic hadronic states being experimentally observed [18].

      In 2015, the LHCb Collaboration observed pentaquark states in the $ J/\psi p $ invariant mass spectrum of $ \Lambda^{0}_b\to{}J/\psi{}K^{-}p{} $ decays. The two candidates of the hidden-charm pentaquark are $ P_{c}(4380) $ and $ P_{c}(4450) $, whose $ J^P $ has an opposite parity with $(\dfrac{3}{2}^{-},\dfrac{5}{2}^{+} )$, [5]. In 2019, the $ P_{c}(4450) $ pentaquark structure was confirmed, and observations revealed that it comprised of two peaks, $ P_{c}(4440) $ and $ P_{c}(4457) $, with a statistical significance of 5.4σ [6]. Meanwhile, the LHCb Collaboration reported a new pentaquark state observation, $ P_{c}(4312) $, with a statistical significance of 7.3σ. In 2021, the LHCb Collaboration found evidence for a new structure, $ P_c(4337) $, in $ B_{s}^{0}\to J/\psi p\bar{p} $ decays, with a final significance of 3.1σ [7]. The mass and width of $ P_c(4337) $ are $ 4337\ ^{+7}_{-4}\ ^{+2}_{-2} $ MeV and $ 29\ ^{+26}_{-12}\ ^{+14}_{-14} $ MeV, respectively, and the parity and angular momentum of $ P_{c}(4337) $ were predicted with $ J^{P}\ =\ {\dfrac{1}{2}}^{+} $ [9].

      Since discovering$ P_c $ states, theorists have shown great interest in explaining the nature of pentaquarks. For instance, in [10], the authors systematically studied the mass spectrum of $ P_c $ states using the chromomagnetic model, and in [11], the magnetic moments of $ P_c $ states were calculated in different color-flavor structures. In addition, the parity and angular momentum of $ P_c $ states were predicted by employing the quark delocalization color screening model [12]. $ P_{c}(4312) $ can be identified as the hidden-charm molecular state $ \Sigma_{c}\bar{D} $ with $ J^{P}=\dfrac{1}{2}^{-} $, and $ P_{c}(4440) $ and $ P_{c}(4457) $ can be identified as the hidden-charm molecular states $ \Sigma_{c}\bar{D}^{*} $ with $ J^{P}=\dfrac{1}{2}^{-} $ and $ \dfrac{3}{2}^{-} $, respectively.

      As more exotic hadrons were observed, theorists have attempted to explain their mass spectra using the one-boson-exchange model [13], QCD sum rules [1419], and effective field theory [2024]. In general, the inner structure of pentaquarks has been classified as molecular [16, 19, 20, 2536], diquark-diquark-antiquark [15, 3740], and diquark-triquark models [4143].

      In 2020, the LHCb Collaboration observed the hidden–charm strange pentaquark $ P_{cs}(4459) $ in the $ J/\psi{}\Lambda $ mass spectrum through an amplitude analysis of the $ \Xi^{-}_b\to{}J/\psi{}\Lambda{}K^{-} $ decay [8]. The mass and width are $ 4458.8\pm 2.9^{+4.7}_{-1.1} $ MeV and $ 17.3\pm 6.5^{+8.0}_{-5.7} $ MeV, respectively, and after an in-depth study of $ P_{cs}(4459) $, the structure was proved to have two resonances, with masses of 4454.9 $ \pm $ 2.7 MeV and 4467.8 $ \pm $ 3.7 MeV and widths of 7.5 $ \pm $ 9.7 MeV and 5.2 $ \pm $ 5.3 MeV, respectively. However, the parity and angular momentum of $ P_{cs}(4459) $ have not been determined experimentally. The predictions of $ J^{P}=\dfrac{1}{2}^{-} $ and $ \dfrac{3}{2}^{-} $ have been given based on QCD sum rules [19], the chiral quark model [25], and the strong decay behaviors of $ P_{cs}(4459) $ [35].

      The encoding of the pentaquark magnetic moment includes helpful details about the charge and magnetization distributions inside hadrons, which assist in analyzing their geometric configurations. In Ref. [44], the author studied the magnetic moments and transition magnetic moments of hidden-charm pentaquark states with coupled channel effects and D wave contributions; this is important because magnetic moments help us understand the inner structure of pentaquarks. In this study, we calculate the magnetic moments of $ P_{cs} $ based on the above three models.

      The remainder of this paper is organized as follows. Sec. II discusses the color factor and color configuration, and Sec. III introduces the wave function of$ P_{cs} $. Sec. IV calculates the magnetic moments of $ P_{cs} $ in the molecular, diquark-diquark-antiquark, and diquark-triquark models. Finally, Sec. V summarizes this study.

    II.   COLOR FACTOR AND COLOR CONFIGURATION
    • The quark level involves chromomagnetic interactions. Therefore, we use the color factor f to indicate whether the color force is attractive or repulsive.

      Regarding the quark-quark color interaction, the color factor f is

      $ \begin{eqnarray} f(ik \rightarrow jl) = \dfrac{1}{4}\sum_{a=1}^{8}\lambda_{ji}^{a}\lambda_{lk}^{a}, \end{eqnarray} $

      (1)

      where $ \lambda^a $ denotes Gell-Mann matrices, and the quark colors are labeled by $ i, j, k $, and l. The potential is

      $ \begin{eqnarray} V_{qq}(r) \approx +f\dfrac{\alpha_s}{r}. \end{eqnarray} $

      (2)

      Considering the quark-antiquark color interaction, the color factor $ \widetilde{f} $ is

      $ \begin{eqnarray} \widetilde{f}(ik \rightarrow jl) = -\dfrac{1}{4}\sum_{a=1}^{8}\lambda_{ji}^{a}\lambda_{lk}^{a}. \end{eqnarray} $

      (3)

      The potential is

      $ \begin{eqnarray} V_{q\bar{q}}(r) \approx +\widetilde{f}\dfrac{\alpha_s}{r}. \end{eqnarray} $

      (4)

      In Table 1, we list the color factors of the multiplet in the SU(3) color representation.

      $ 3_{c}\ \otimes\ \bar{3}_{c} $$ 1_{c}\ \oplus\ {8}_{c} $
      color factor$ -\dfrac{4}{3}\;\; \dfrac{1}{6}$
      $ 3_{c}\ \otimes\ 3_{c} $$ 6_{c}\ \oplus\ \bar{3}_{c} $
      color factor$ \dfrac{1}{3} \;\;-\dfrac{2}{3} $
      $ 3_{c}\ \otimes\ {3}_{c}\otimes\ {3}_{c} $$ 1_{c}\ \oplus\ {8}_{1c}\ \oplus\ {8}_{2c}\ \oplus\ {10}_{c} $
      color factor$ -2\;\;-\dfrac{1}{2} \;\; -\dfrac{1}{2}\;\;1$
      $ 3_{c}\ \otimes\ {3}_{c}\otimes\ \bar{3}_{c} $$ 3_{1c}\ \oplus\ 3_{2c}\ \oplus\ \bar{6}_{c}\ \oplus\ {15}_{c} $
      color factor$ -\dfrac{4}{3} \;\;-\dfrac{4}{3}\;\;-\dfrac{1}{3}\;\;2$

      Table 1.  Color factor values for color representation.

      Color confinement implies that physical hadrons are singlets. Under this restriction, we divide the pentaquark states into the following three categories:

      1. Molecular model

      Each cluster of the molecular model forms a quasibound cluster. In other words, clusters of the molecular model tend to be color singlets. We observe that $ f_{1_{c}} < f_{8_{c}} $ in the color representation of the quark and antiquark; hence, it is easier to form a singlet state than octet states. Similarly, $ f_{1_{c}} < f_{8_{1c}}/f_{8_{2c}}< f_{10_{c}} $ in the three-quark color representation, and thus it is easier to form a singlet state than other states. Therefore, from the molecular model, we have two configurations, $ (c\bar{c})(q_{1}q_{2}q_{3}) $ and $ (\bar{c}q_{1})({c}q_{2}q_{3}) $, where q denotes the $ u,d,s $ quark.

      2. Diquark-Diquark-antiquark model

      The diquark prefers to form $ \bar{3}_{c} $ by comparing the color factors of $ 6_{c} $ and $ \bar{3}_{c} $. Similarly, $ \bar{3}_{c}\ \otimes\ \bar{3}_{c} $ prefers to form $ 3_{c} $. Hence, we have $ \bar{3}_{c}(\mathcal{D})\ \otimes\ \bar{3}_{c}(\mathcal{D})\ \otimes\ \bar{3}_{c}(\mathcal{A}) $ to form a color singlet, where $ \mathcal{D} $ and $ \mathcal{A} $ represent the diquark and antiquark, respectively. Thus, the pentaquark configuration is $ (cq_{1})(q_{2}q_{3})(\bar{c}) $, represented by the diquark-diquark-antiquark model.

      3. Diquark-triquark model

      The triquark involves two quarks and an antiquark, which distinguish it from the molecule model. In this case, $ f_{3_{1c}} / f_{3_{2c}} < f_{\bar{6}_{c}} < f_{15_{c}} $ is the color representation of the triquark quark, and we have $ 3_{c}(\mathcal{T})\ \otimes \ \bar{3}_{c}(\mathcal{D}) $ to form a color singlet, where $ \mathcal{T} $ represents a triquark. Thus, the pentaquark configurations represented by the diquark-triquark model are $ (c\bar{c}q_{1})(q_{2}q_{3}) $ and $ (cq_{1})(\bar{c}q_{2}q_{3}) $.

      The separation of c and $ \bar{c} $ into distinct confinement volumes provides a natural suppression mechanism for the pentaquark widths [6]. Thus, we do not consider $ (\bar{c}c) (q_{1}q_{2}q_{3}) $ and $ (\bar{c}cq_{1})(q_{2}q_{3}) $.

    III.   WAVE FUNCTION OF HIDDEN-CHARM STRANGE PENTAQUARK STATES
    • In this study, we investigate pentaquark states in the $S U(3)_{f}$ frame. The overall wavefunction for a bounded multiquark state, while accounting for all degrees of freedom, can be written as

      $ \begin{equation} \psi_{\rm wavefunction} = \phi_{\rm flavor}\chi_{\rm spin}\varepsilon_{\rm color}\eta_{\rm space}. \nonumber \end{equation} $

      Owing to Fermi statistics, the overall wavefunction above must be antisymmetric.

      The molecular model of the pentaquark is composed of mesons and baryons, which must be color singlets because of color confinement. The relationship between spin and flavor is $\phi_{\rm flavor}\chi_{\rm spin}$ = symmetric because the color wavefunction is antisymmetric and the spatial wavefunction is symmetric in the ground state. We study the $ P_{cs} $ state in a $S U(3)_f$ frame. There are two configurations for $ q_{2}q_{3} $, where $ q_{2}q_{3} $ forms the $ \bar{3}_f $ and $ 6_f $ flavor representations with the total spin S = 0 and 1, respectively. When $ q_{2}q_{3} $ forms $ 6_f $, it is combined with $ q_1 $ to form the flavor representation $ 6_f\ \otimes\ {3}_{f} $ = $ 10_f\ \oplus\ 8_{1f} $, whereas when $ q_{2}q_{3} $ forms $ \bar{3}_f $, it is combined with $ q_1 $ to form the flavor representation $ \bar{3}_f\ \otimes\ {3}_{f} $ = $ 8_{2f}\ \oplus\ 1_f $. After inserting $ [c\bar{c}] $ and the Clebsch-Gordan coefficients, we apply the same method to the $ (cq_{1})(q_{2}q_{3})(\bar{c}) $ and $ (cq_{1})(\bar{c}q_{2}q_{3}) $configurations and obtain the flavor wave function of$ P_{cs} $ in $ 8_{1f} $ and $ 8_{2f} $. The results are reported in Table 2.

      ModelMultiplet$ (I,I_{3}) $Wave function
      Molecular model$ 8_{1f} $$ (1,0) $$ \dfrac{1}{\sqrt6}[({\bar c}d)(c\{us\})+({\bar c}u)(c\{ds\})]-\sqrt{\dfrac{2}{3}}({\bar c}s)(c\{ud\}) $
      $ (0,0) $$ \dfrac{1}{\sqrt2}[({\bar{c}}u)(c\{ds\})-({\bar{c}}d)(c\{us\})] $
      $ 8_{2f} $$ (1,0) $$ \dfrac{1}{\sqrt2}\{ ({\bar c}d)(c[us])+({\bar c}u)(c[ds]) \} $
      $ (0,0) $$ \dfrac{1}{\sqrt6}\{({\bar c}d)(c[us])-({\bar c}u)(c[ds])-2(\bar c s)(c[ud])\} $
      Diquark-diquark-antiquark model$ 8_{1f} $$ (1,0) $$ \dfrac{1}{\sqrt6}[({c}d)\{us\}{\bar c}+({c}u)\{ds\}{\bar c}]-\sqrt{\dfrac{2}{3}}({c}s)\{ud\}{\bar c} $
      $ (0,0) $$ \dfrac{1}{\sqrt2}[({c}u)\{ds\}{\bar c}-({c}d)\{us\}{\bar c}] $
      $ 8_{2f} $$ (1,0) $$ \dfrac{1}{\sqrt2}\{ (cd)[us]{\bar c}+(cu)[ds]{\bar c} \} $
      $ (0,0) $$ \dfrac{1}{\sqrt6} \{ (cd)[us]{\bar c}-(cu)[ds]{\bar c}-2(cs)[ud]{\bar c} \} $
      Diquark-triquark model$ 8_{1f} $$ (1,0) $$ \dfrac{1}{\sqrt6}[({c}d)(\bar c\{us\})+({c}u)(\bar c\{ds\})]-\sqrt{\dfrac{2}{3}}({c}s)(\bar c\{ud\}) $
      $ (0,0) $$ \dfrac{1}{\sqrt2}[({c}u)(\bar c\{ds\})-({c}d)(\bar c\{us\})] $
      $ 8_{2f} $$ (1,0) $$ \dfrac{1}{\sqrt2}\{ ({c}d)(\bar c[us])+({c}u)(\bar c[ds]) \} $
      $ (0,0) $$ \dfrac{1}{\sqrt6}\{({c}d)(\bar c[us])-({ c}u)(\bar c[ds])-2( c s)(\bar c[ud])\} $

      Table 2.  Flavor wave function of hidden–charm strange pentaquark states in different models.

    IV.   MAGNETIC MOMENTS OF THE HIDDEN$ – $CHARM STRANGE PENTAQUARK

      A.   Magnetic moments of the molecular model with the configuration$ (\bar{c}q_1)(cq_2q_3) $

    • Because quarks are fundamental Dirac fermions, the operators of the total magnetic moments and z-component are

      $ \begin{eqnarray} \hat{\mu} = \ Q\dfrac{e}{m}\hat{S}, \ \ \ \ \ \ \ \hat{\mu_{z}} = \ Q\dfrac{e}{m}\hat{S_{z}}. \end{eqnarray} $

      (5)

      As mentioned above, we do not consider the orbital excitation in the bound state; hence, the orbital excitation lies between the meson and baryon. The total magnetic moment formula can be written as

      $ \begin{eqnarray} \hat{\mu} = \ \hat{\mu}_{\mathcal{B}}+\hat{\mu}_{\mathcal{M}}+\hat{\mu}_{l}, \end{eqnarray} $

      (6)

      where the subscripts $ \mathcal{B} $ and $ \mathcal{M} $ represent the baryon and meson, respectively, and l is the orbital excitation between the meson and baryon. The specific forms of the magnetic moments can be written as

      $ \begin{eqnarray} \hat{\mu}_{\mathcal{B}} = \sum_{i=1}^{3} \mu_{i}g_{i}\hat{S}_{i}, \end{eqnarray} $

      (7)

      $ \begin{eqnarray} \hat{\mu}_{\mathcal{M}} = \sum_{i=1}^{2} \mu_{i}g_{i}\hat{S}_{i}, \end{eqnarray} $

      (8)

      $ \begin{eqnarray} \hat{\mu}_{l} = \mu_{l}\hat{l} = \dfrac{M_{\mathcal{M}}\mu_{\mathcal{B}}+M_{\mathcal{B}}\mu_{\mathcal{M}}}{M_{\mathcal{M}}+M_{\mathcal{B}}}\hat{l}, \end{eqnarray} $

      (9)

      where $ g_{i} $ is the Lande factor, and $ M_{\mathcal{M}} $ and $ M_{\mathcal{B}} $ are the meson and baryon masses, respectively. The $ (\bar{c}q_1)(cq_2q_3) $ specific magnetic moment formula of the pentaquark in the molecular model is

      $ \begin{aligned}[b] \mu =& \langle\ \psi\ |\ \hat{\mu}_{\mathcal{B}}+\hat{\mu}_{\mathcal{M}}+\hat{\mu}_{l}\ |\ \psi\ \rangle = \sum_{SS_z,ll_z}\ \langle\ SS_z,ll_z|JJ_z\ \rangle^{2} \\&\times \Bigg\{ \mu_{l} l_z + \sum_{\widetilde{S}_\mathcal{B},\widetilde{S}_\mathcal{M}}\ \langle\ S_\mathcal{B} \widetilde{S}_{\mathcal{B}},S_\mathcal{M} \widetilde{S}_{\mathcal{M}}|SS_z\ \rangle^{2} \Bigg [ \widetilde{S}_{\mathcal{M}}\bigg(\mu_{\bar{c}} + \mu_{q_1}\bigg ) \end{aligned} $

      $ \begin{aligned}[b]\quad\quad &+ \sum_{\widetilde{S}_{c}}\ \langle\ S_c \widetilde{S}_{c},S_{r} \widetilde{S}_{\mathcal{B}}-\widetilde{S}_{c}|S_\mathcal{B} \widetilde{S}_{\mathcal{B}}\rangle^{2}\\&\times \bigg(g\mu_{c}\widetilde{S}_{c}+(\widetilde{S}_{\mathcal{B}}-\widetilde{S}_{c})(\mu_{q_{2}}+\mu_{q_{3}})\bigg ) \Bigg ]\Bigg\}, \end{aligned} $

      (10)

      where ψ represents the wave function in Table 2, $ S_\mathcal{M} $, $ S_\mathcal{B} $, and $ S_r $ are the meson, baryon, and diquark spin inside the baryon, respectively, and $ \widetilde{S} $ is the third spin component.

      For example, the recently observed $ P_{cs}(4459) $ state is supposed to be the $ \bar{D}^{*}\Xi_{c} $ molecular state in the $ 8_{2f} $ representation with $ (I,I_{3}) = (0,0) $. Its flavor wave functions are

      $ \begin{equation} | P_{cs}\rangle = \dfrac{1}{\sqrt{6}}\{({\bar c}d)(c[us])-({\bar c}u)(c[ds])-2(\bar c s)(c[ud])\}. \end{equation} $

      (11)

      Take $ J^{p}={\dfrac{1}{2}}^{-} $ ($ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $) as an example. $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}} $ correspond to the angular momentum and parity of the baryon, meson, and orbital, respectively.

      $ \begin{aligned}[b]\\[-3pt] \mu = & \langle\ P_{cs}\ |\ \hat{\mu}_{\mathcal{B}}+\hat{\mu}_{\mathcal{M}}+\hat{\mu}_{l}\ |\ P_{cs}\ \rangle \\=& \langle \dfrac{1}{2}\dfrac{1}{2},1 0 |\dfrac{1}{2}\dfrac{1}{2}\rangle^{2}\Bigg [ \langle \dfrac{1}{2}\dfrac{1}{2},0 0 |\dfrac{1}{2}\dfrac{1}{2}\rangle^{2} \Bigg (\dfrac{1}{6}*\dfrac{1}{2}g\mu_{c}+\dfrac{1}{6}*\dfrac{1}{2}g\mu_{c}+\dfrac{4}{6}*\dfrac{1}{2}g\mu_{c}\Bigg )\Bigg ] \\ & + \langle \dfrac{1}{2}-\dfrac{1}{2},1 1 |\dfrac{1}{2}\dfrac{1}{2}\rangle^{2}\Bigg [ \Bigg (\dfrac{1}{6}*(\dfrac{1}{2}g\mu_{\bar{c}}+\dfrac{1}{2}g\mu_{d})+\dfrac{1}{6}*(\dfrac{1}{2}g\mu_{\bar{c}}+\dfrac{1}{2}g\mu_{u})+\dfrac{4}{6}*(\dfrac{1}{2}g\mu_{\bar{c}}+\dfrac{1}{2}g\mu_{s})\Bigg ) \\ & + \langle \dfrac{1}{2}-\dfrac{1}{2},0 0 |\dfrac{1}{2}-\dfrac{1}{2}\rangle^{2} \Bigg (\dfrac{1}{6}*-\dfrac{1}{2}g\mu_{c}+\dfrac{1}{6}*-\dfrac{1}{2}g\mu_{c}+\dfrac{4}{6}*-\dfrac{1}{2}g\mu_{c}\Bigg )\Bigg ] \\ = & \dfrac{1}{9} (\mu_{u}+\mu_{d}+4\mu_{s}+6\mu_{\bar{c}}-3\mu_{c} ). \end{aligned} $

      (12)

      In this study, we use the following constituent quark masses [45]:

      $\begin{aligned}[b] m_u =& m_d = 0.336\ \rm{GeV}, \\ m_s =& 0.540\ \rm{GeV},\\ m_c =& 1.660\ \rm{GeV}. \end{aligned} $

      The numerical results with isospin $ (I,I_3) = (1,0) $ and $ (I,I_3) = (0,0) $ are shown in Tables 3 and 4, respectively.

      $8_{1f}: \dfrac{1}{\sqrt6}[({\bar c}d)(c\{us\})+({\bar c}u)(c\{ds\})]-\sqrt{\dfrac{2}{3} }({\bar c}s)(c\{ud\})$
      $ ^{2}S_{\frac{1}{2}} $ ($J^P={\dfrac{1}{2} }^{-}$)$ {^{4}S_{\frac{3}{2}}} $(${J^P={\dfrac{3}{2} }^{-} }$)$ ^{6}S_{\frac{5}{2}}^{-} $($J^P={\dfrac{5}{2} }^{-}$)
      $ (Y, I, I_3) $${\dfrac{1}{2} }^{+}\otimes0^{-}\otimes0^{+}$${\dfrac{1}{2} }^{+}\otimes1^{-}\otimes0^{+}$${\dfrac{3}{2} }^{+}\otimes1^{-}\otimes0^{+}$${\dfrac{1}{2} }^{+}\otimes1^{-}\otimes0^{+}$$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes0^{+} $$ {\dfrac{3}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{3}{2}}^{+}\otimes1^{-}\otimes0^{+} $
      $ (0,1,0) $0.263−0.4930.735−0.3450.9590.4600.352
      $ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\dfrac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\dfrac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,1,0) $−0.1450.125−0.2890.564−0.1720.278
      $ {^{2}P_{\frac{3}{2}}} $($ {J^P={\dfrac{3}{2}}^{+}} $)$ {^{4}P_{\frac{3}{2}}} $($ {J^P={\dfrac{3}{2}}^{+}} $)$ {^{6}P_{\frac{3}{2}}} $($ {J^P={\dfrac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{5}{2}}\otimes1^{-} $
      $ (0,1,0) $0.177−0.5510.6690.666−0.2760.3110.335
      $ {^{4}P_{\frac{5}{2}}} $ ($ {J^P={\dfrac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\dfrac{5}{2}}^{+}} $)$ {^{6}P_{\frac{7}{2}}} $ ($ {J^P={\dfrac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{5}{2}}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes1^{-}\otimes1^{-} $
      $ (0,1,0) $−0.4030.8650.3940.2920.285
      $ 8_{2f} $: $ \dfrac{1}{\sqrt2}\{ ({\bar c}d)(c[us])+({\bar c}u)(c[ds]) \} $
      $ ^2S_{\frac{1}{2}} $($J^P={\dfrac{1}{2} }^{-}$)$ ^{4}S_{{\frac{3}{2}}} $(${J^P={\dfrac{3}{2} }^{-} }$)$ {^{2}P_{\frac{1}{2}}} $(${J^P={\dfrac{1}{2} }^{+} }$)$ {^{4}P_{\frac{1}{2}}} $($ {J^P={\dfrac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,1,0) $0.377−0.0670.465−0.167−0.0070.273
      $ ^{2}P_{\frac{3}{2}} $ ($ J^P={\dfrac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $ ($ J^P={\dfrac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $ (${J^P={\dfrac{5}{2} }^{+} }$)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes0^{-}]_{\frac{3}{2}}\otimes1^{-} $${\dfrac{1}{2} }^{+}\otimes1^{-}\otimes1^{-}$$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes1^{-} $
      $ (0,1,0) $0.315−0.1100.3240.422

      Table 3.  Magnetic moments of pentaquark states in the molecular model with the wavefunction $\dfrac{1}{\sqrt6}[({\bar c}d)(c\{us\})+ $$ ({\bar c}u)(c\{ds\})]-\sqrt{\dfrac{2}{3}}({\bar c}s)(c\{ud\})$ in $ 8_{1f} $ and $\dfrac{1}{\sqrt2}\{ ({\bar c}d)(c[us])+({\bar c}u)(c[ds]) \}$ in $ 8_{2f} $ with isospin $ (I,I_3) = (1,0) $. They are in the $ 8_{1f} $ representation from $ 6_f \otimes 3_f = 10_f \oplus 8_{1f} $ and the $ 8_{2f} $ representation from $ \bar{3}_f \otimes 3_f = 1_f \oplus8_{2f} $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}} $ correspond to the angular momentum and parity of the baryon, meson, and orbital, respectively. The unit is proton magnetic moments.

      $ 8_{1f} $: $\dfrac{1}{\sqrt2}[({\bar{c} }u)(c\{ds\})-({\bar{c} }d)(c\{us\})]$
      $ ^{2}S_{\frac{1}{2}} $($J^P={\dfrac{1}{2} }^{-}$)$ {^{4}S_{\frac{3}{2}}} $(${J^P={\dfrac{3}{2} }^{-} }$)$ ^{6}S_{\frac{5}{2}}^{-} $($J^P={\dfrac{5}{2} }^{-}$)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{3}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes0^{+} $$ {\dfrac{3}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{3}{2}}^{+}\otimes1^{-}\otimes0^{+} $
      $ (0,0,0) $−0.2010.1260.117−0.1130.2630.2280.352
      $ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\dfrac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\dfrac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,0,0) $0.021−0.076−0.076−0.0460.1710.145
      $ {^{2}P_{\frac{3}{2}}} $($ {J^P={\dfrac{3}{2}}^{+}} $)$ {^{4}P_{\frac{3}{2}}} $($ {J^P={\dfrac{3}{2}}^{+}} $)$ {^{6}P_{\frac{3}{2}}} $ ($ {J^P={\dfrac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{5}{2}}\otimes1^{-} $
      $ (0,0,0) $−0.2700.0750.061−0.1030.1630.1450.329
      $ {^{4}P_{\frac{5}{2}}} $ ($ {J^P={\dfrac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\dfrac{5}{2}}^{+}} $)$ {^{6}P_{\frac{7}{2}}} $ ($ {J^P={\dfrac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $$ [{\dfrac{3}{2}}^{+}\otimes1^{-}]_{\frac{5}{2}}\otimes1^{-} $$ {\dfrac{3}{2}}^{+}\otimes1^{-}\otimes1^{-} $
      $ (0,0,0) $−0.1640.1890.1720.2950.296
      $ 8_{2f} $: $ \dfrac{1}{\sqrt6} \{ ({\bar c}d)(c[us])-({\bar c}u)(c[ds])-2(\bar c s)(c[ud]) \} $
      $ ^2S_{\frac{1}{2}} $($ J^P={\dfrac{1}{2}}^{-} $)$ ^{4}S{{\dfrac{3}{2}}} $($ {J^P={\dfrac{3}{2}}^{-}} $)$ {^{2}P_{\frac{1}{2}}} $($ {J^P={\dfrac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $($ {J^P={\dfrac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{1}{2}}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes1^{-}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,0,0) $0.377−0.531−0.231−0.1610.152−0.116
      $ ^{2}P_{\frac{3}{2}} $ ($ J^P={\dfrac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $ ($ J^P={\dfrac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $($ {J^P={\dfrac{5}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\dfrac{1}{2}}^{+}\otimes0^{-}\otimes1^{-} $$ [{\dfrac{1}{2}}^{+}\otimes0^{-}]_{\frac{3}{2}}\otimes1^{-} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes1^{-} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes1^{-} $
      $ (0,0,0) $0.324−0.568−0.184−0.268

      Table 4.  Magnetic moments of pentaquark states in the molecular model with the wavefunction $\dfrac{1}{\sqrt2}[({\bar{c}}u)(c\{ds\})-({\bar{c}}d)(c\{us\})]$ in $ 8_{1f} $ and $\dfrac{1}{\sqrt6} \{ ({\bar c}d)(c[us])-({\bar c}u)(c[ds])-2(\bar c s)(c[ud]) \}$ in $ 8_{2f} $ with isospin $ (I,I_3) = (0,0) $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}} $ correspond to the angular momentum and parity of the baryon, meson, and orbital, respectively. The unit is proton magnetic moments.

    • B.   Magnetic moments of the diquark-diquark-antiquark model with the $ (cq_1)(q_2q_3)\bar{c} $ configuration

    • In the diquark-diquark-antiquark model, there are two P-wave excitation modes inside the three-body bound state: ρ and λ excitation. ρ mode P-wave orbital excitation lies between the diquark $ (cq_1) $ and diquark $ (q_2q_3) $, whereas λ mode P-wave orbital excitation lies between $ \bar{c} $ and the center of mass system of $ (cq_1) $ and $ (q_2q_3) $.

      The total magnetic moment formula of the diquark-diquark-antiquark model can be written as

      $ \begin{eqnarray} \hat{\mu} = \ \hat{\mu}_{H}+\hat{\mu}_{L}+\hat{\mu}_{\bar{c}}+\hat{\mu}_{l}, \end{eqnarray} $

      (13)

      where the subscripts H and L represent heavy $ (cq_1) $ and light diquarks $ (q_2q_3) $, respectively, and l is the orbital excitation. In the diquark-diquark-antiquark model, the specific magnetic moment formula of the pentaquark $ (cq_1)(q_2q_3)\bar{c} $ is

      $ \begin{aligned}[b]\\[536pt] \mu =& \langle\ \psi \ |\ \hat{\mu}_{H}+\hat{\mu}_{L}+\hat{\mu}_{\bar{c}}+\hat{\mu}_{l}\ |\ \psi \ \rangle =\sum_{S_z,l_z}\ \langle\ SS_z,ll_z|JJ_z\ \rangle^{2} \left \{ \mu_{l} l_z + \sum_{\widetilde{S}_{\bar{c}}}\ \langle\ S_{\bar{c}} \widetilde{S}_{\bar{c}},S_{\mathcal{G}} \widetilde{S}_{\mathcal{G}}|SS_z\ \rangle^{2} \Bigg [g\widetilde{S}_{\bar{c}}\mu_{\bar{c}}\right.\\ &+\left.\sum_{\widetilde{S}_{H},\widetilde{S}_{L}}\ \langle\ S_{H} \widetilde{S}_{H},S_{L} \widetilde{S}_{L}|S_{\mathcal{G}} \widetilde{S}_{\mathcal{G}}\rangle^{2}\bigg(\widetilde{S}_{H}(\mu_{c}+\mu_{q_1})+\widetilde{S}_{L}(\mu_{q_2}+\mu_{q_3})\bigg ) \Bigg ]\right \},\\ \end{aligned} $

      (14)

      where $ S_{\mathcal{G}} $ represents the spin of $ (cq_1)(q_2q_3) $. The diquark masses are [46]

      $ \begin{aligned}[b] [u,d]=& 710\;{\rm{ MeV}}, \quad \{u,d\} =909\;{ \rm{MeV}},\quad [u,s]=948\;{\rm{ MeV}},\\ \{u,s\} =&1069\;{\rm{ MeV}},\quad [c,q]= 1973\;{\rm{ MeV}},\;\;\{c,q\} =2036\;{\rm{ MeV}},\\ [c,s]=&2091\;{\rm{ MeV}},\quad\{c,s\} =2158\;{\rm{ MeV}}. \end{aligned} $

      The numerical results for states with the ρ excitation mode and isospin $ (I,I_3) = (1,0) $ and $ (I,I_3) = (0,0) $ are presented in Tables 5 and 6, respectively. The numerical results for states with the λ excitation mode and isospin $ (I,I_3) = (1,0) $ and $ (I,I_3) = (0,0) $ are presented in Tables 7 and 8, respectively.

      $ 8_{1f} $: $ \frac{1}{\sqrt6}[({c}d)\{us\}{\bar c}+({c}u)\{ds\}{\bar c}]-\sqrt{\frac{2}{3}}({c}s)\{ud\}{\bar c} $
      $ ^{2}S_{\frac{1}{2}} $($ J^P={\frac{1}{2}}^{-} $)$ {^{4}S_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ ^{6}S_{\frac{5}{2}} $ ($ J^P={\frac{5}{2}}^{-} $)
      $ (Y, I, I_3) $$ 0^{+}\otimes1^{+} \otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{0} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (0^{+}\otimes1^{+})\otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{2} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})\otimes {\frac{1}{2}}^{-}\otimes0^{+} $
      $ (0,1,0) $0.514−0.3770.3680.206−0.0130.8810.352
      $ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $
      $ (0,1,0) $−0.0350.0460.2600.012−0.0740.422
      $ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^6 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $
      $ (0,1,0) $0.7190.233−0.1750.5700.0050.7270.174
      $ {^{4}P_{\frac{5}{2}}^{+}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^6P_{\frac{7}{2}}} $ ($ {J^P={\frac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $$ 1^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-}\otimes1^{-} $
      $ (0,1,0) $0.4100.1901.0830.3690.554
      $ 8_{2f} $: $ \frac{1}{\sqrt2}\{ (cd)[us]{\bar c}+(cu)[ds]{\bar c} \} $
      $ ^2S_{\frac{1}{2}} $ ($ J^P={\frac{1}{2}}^{-} $)$ ^{4}S{{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{-}} $)$ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ 0^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes{1^{-}} $
      $ (0,1,0) $−0.3770.6870.4650.137−0.2240.256
      $ ^{2}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $($ {J^P={\frac{5}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} )_{\frac{1}{2}}\otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}} \otimes{1^{-}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $
      $ (0,1,0) $−0.3600.6950.3440.473

      Table 5.  Magnetic moments of pentaquark states in the diquark-diquark-antiquark model with the wave function$ \frac{1}{\sqrt6}[({c}d)\{us\}{\bar c}+({c}u)\{ds\}{\bar c}]-\sqrt{\frac{2}{3}}({c}s)\{ud\}{\bar c} $ in $ 8_{1f} $ and $ \frac{1}{\sqrt2}\{ (cd)[us]{\bar c}+(cu)[ds]{\bar c} \} $ in $ 8_{2f} $ with isospin $ (I,I_3) = (1,0) $. They are in the $ 8_{1f} $ representation from $ 6_f \otimes 3_f = 10_f \oplus 8_{1f} $ and the $ 8_{2f} $ representation from $ \bar{3}_f \otimes 3_f = 1_f \oplus8_{2f} $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}}\otimes J_{4}^{P_{4}} $ correspond to the angular momentum and parity of $ (cq_1) $, $ (q_2q_3) $, $ \bar{c} $, and the orbital, respectively. ρ mode P-wave orbital excitation lies between the diquark $ (cq_1) $ and diquark $ (q_2q_3) $. The unit is proton magnetic moments.

      $ 8_{1f} $: $ \frac{1}{\sqrt2}[({c}u)\{ds\}{\bar c}-({c}d)\{us\}{\bar c}] $
      $ ^{2}S_{\frac{1}{2}} $($ J^P={\frac{1}{2}}^{-} $)$ {^{4}S_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ ^{6}S_{\frac{5}{2}} $ ($ J^P={\frac{5}{2}}^{-} $)
      $ (Y, I, I_3) $$ 0^{+}\otimes1^{+} \otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{0} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (0^{+}\otimes1^{+})\otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{2} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})\otimes {\frac{1}{2}}^{-}\otimes0^{+} $
      $ (0,0,0) $0.050−0.3770.368−0.490−0.0130.8810.352
      $ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $
      $ (0,0,0) $0.013−0.2870.150−0.098−0.0190.478
      $ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^6 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $
      $ (0, 0,0) $0.094−0.342−0.3400.4050.1970.6610.273
      $ {^{4}P_{\frac{5}{2}}^{+}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^6P_{\frac{7}{2}}} $ ($ {J^P={\frac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $$ 1^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-}\otimes1^{-} $
      $ (0,0,0) $−0.4460.0240.9180.3220.388
      $ 8_{2f} $: $ \frac{1}{\sqrt6} \{ (cd)[us]{\bar c}-(cu)[ds]{\bar c}-2(cs)[ud]{\bar c} \} $
      $ ^2S_{\frac{1}{2}} $ ($ J^P={\frac{1}{2}}^{-} $)$ ^{4}S{{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{-}} $)$ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ 0^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes{1^{-}} $
      $ (0,0,0) $−0.3770.223−0.2310.2920.091−0.211
      $ ^{2}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $($ {J^P={\frac{5}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} )_{\frac{1}{2}}\otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}} \otimes{1^{-}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $
      $ (0,0,0) $−0.1260.470−0.0700.016

      Table 6.  Magnetic moments of pentaquark states in the diquark-diquark-antiquark model with the wave function$ \frac{1}{\sqrt2}[({c}u)\{ds\}{\bar c}-({c}d)\{us\}{\bar c}] $ in $ 8_{1f} $ and $ \frac{1}{\sqrt6} \{ (cd)[us]{\bar c}-(cu)[ds]{\bar c}-2(cs)[ud]{\bar c} \} $ in $ 8_{2f} $ with isospin $ (I,I_3) = (0,0) $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}}\otimes J_{4}^{P_{4}} $ correspond to the angular momentum and parity of $ (cq_1) $, $ (q_2q_3) $, $ \bar{c} $, and the orbital, respectively. ρ mode P-wave orbital excitation lies between the diquark $ (cq_1) $ and diquark $ (q_2q_3) $.

      $ 8_{1f} $: $ \frac{1}{\sqrt6}[({c}d)\{us\}{\bar c}+({c}u)\{ds\}{\bar c}]-\sqrt{\frac{2}{3}}({c}s)\{ud\}{\bar c} $
      $ ^{2}S_{\frac{1}{2}} $($ J^P={\frac{1}{2}}^{-} $)$ {^{4}S_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ ^{6}S_{\frac{5}{2}} $ ($ J^P={\frac{5}{2}}^{-} $)
      $ (Y, I, I_3) $$ 0^{+}\otimes1^{+} \otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{0} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (0^{+}\otimes1^{+})\otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{2} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})\otimes {\frac{1}{2}}^{-}\otimes0^{+} $
      $ (0,1,0) $0.514−0.3770.3680.206−0.0130.8810.352
      $ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $
      $ (0,1,0) $0.217−0.0800.5070.259−0.1980.299
      $ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^6 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $
      $ (0,1,0) $1.0960.3840.1960.9410.2200.875−0.048
      $ {^{4}P_{\frac{5}{2}}^{+}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^6P_{\frac{7}{2}}} $ ($ {J^P={\frac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $$ 1^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-}\otimes1^{-} $
      $ (0,1,0) $0.7880.5601.4540.4750.924
      $ 8_{2f} $: $ \frac{1}{\sqrt2}\{ (cd)[us]{\bar c}+(cu)[ds]{\bar c} \} $
      $ ^2S_{\frac{1}{2}} $ ($ J^P={\frac{1}{2}}^{-} $)$ ^{4}S{{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{-}} $)$ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ 0^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes{1^{-}} $
      $ (0,1,0) $−0.3770.6870.4650.5250.1640.062
      $ ^{2}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $($ {J^P={\frac{5}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} )_{\frac{1}{2}}\otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}} \otimes{1^{-}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $
      $ (0,1,0) $0.2231.2770.5771.055

      Table 7.  Magnetic moments of pentaquark states in the diquark-diquark-antiquark model with the wave function$ \frac{1}{\sqrt6}[({c}d)\{us\}{\bar c}+({c}u)\{ds\}{\bar c}]-\sqrt{\frac{2}{3}}({c}s)\{ud\}{\bar c} $ in $ 8_{1f} $ and $ \frac{1}{\sqrt2}\{ (cd)[us]{\bar c}+(cu)[ds]{\bar c} \} $ in $ 8_{2f} $ with isospin $ (I,I_3) = (1,0) $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}}\otimes J_{4}^{P_{4}} $ correspond to the angular momentum and parity of $ (cq_1) $, $ (q_2q_3) $, $ \bar{c} $, and the orbital, respectively. λ mode P-wave orbital excitation lies between $ \bar{c} $ and the center of mass system of $ (cq_1) $ and $ (q_2q_3) $.The unit is proton magnetic moments.

      $ 8_{1f} $: $ \frac{1}{\sqrt2}[({c}u)\{ds\}{\bar c}-({c}d)\{us\}{\bar c}] $
      $ ^{2}S_{\frac{1}{2}} $($ J^P={\frac{1}{2}}^{-} $)$ {^{4}S_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ ^{6}S_{\frac{5}{2}} $ ($ J^P={\frac{5}{2}}^{-} $)
      $ (Y, I, I_3) $$ 0^{+}\otimes1^{+} \otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{0} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (0^{+}\otimes1^{+})\otimes{\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{1} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})_{2} \otimes {\frac{1}{2}}^{-}\otimes0^{+} $$ (1^{+}\otimes1^{+})\otimes {\frac{1}{2}}^{-}\otimes0^{+} $
      $ (0,0,0) $0.050−0.3770.368−0.490−0.0130.8810.352
      $ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{2}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ ^{4}P_{\frac{1}{2}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $
      $ (0,0,0) $0.334−0.4480.4690.221−0.1790.318
      $ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^2 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^4 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)$ {^6 P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{0}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $
      $ (0, 0,0) $0.575−0.1500.1390.8840.0720.853−0.014
      $ {^{4}P_{\frac{5}{2}}^{+}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^6P_{\frac{7}{2}}} $ ($ {J^P={\frac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ (0^{+}\otimes1^{+}\otimes {\frac{1}{2}}^{-})\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{1}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes1^{-} $$ ((1^{+}\otimes1^{+})_{2}\otimes{\frac{1}{2}}^{-})_{\frac{5}{2}}\otimes1^{-} $$ 1^{+}\otimes1^{+}\otimes{\frac{1}{2}}^{-}\otimes1^{-} $
      $ (0,0,0) $0.0350.5031.3970.4590.867
      $ 8_{2f} $: $ \frac{1}{\sqrt6} \{ (cd)[us]{\bar c}-(cu)[ds]{\bar c}-2(cs)[ud]{\bar c} \} $
      $ ^2S_{\frac{1}{2}} $ ($ J^P={\frac{1}{2}}^{-} $)$ ^{4}S{{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{-}} $)$ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{0^{+}} $$ 0^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{1}{2}} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}}\otimes{1^{-}} $
      $ (0,0,0) $−0.3770.223−0.2310.6160.410−0.370
      $ ^{2}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $($ J^P={\frac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $($ {J^P={\frac{5}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {0}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} )_{\frac{1}{2}}\otimes{1^{-}} $$ ({1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-})_{\frac{3}{2}} \otimes{1^{-}} $$ {1}^{+}\otimes0^{+}\otimes{\frac{1}{2}}^{-} \otimes{1^{-}} $
      $ (0,0,0) $0.3590.9490.1210.495

      Table 8.  Magnetic moments of pentaquark states in the diquark-diquark-antiquark model with the wave function$ \frac{1}{\sqrt2}[({c}u)\{ds\}{\bar c}-({c}d)\{us\}{\bar c}] $ in $ 8_{1f} $ and $ \frac{1}{\sqrt6} \{ (cd)[us]{\bar c}-(cu)[ds]{\bar c}-2(cs)[ud]{\bar c} \} $ in $ 8_{2f} $ with isospin $ (I,I_3) = (0,0) $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}}\otimes J_{4}^{P_{4}} $ correspond to the angular momentum and parity of $ (cq_1) $, $ (q_2q_3) $, $ \bar{c} $, and the orbital, respectively. λ mode P-wave orbital excitation lies between $ \bar{c} $ and the center of mass system of $ (cq_1) $ and $ (q_2q_3) $.

    • C.   Magnetic moments of the diquark-triquark model with the configuration$ (cq_1)(\bar{c}q_2q_3) $

    • Considering the diquark-triquark model, the total magnetic moment formula is

      $ \begin{eqnarray} \hat{\mu} = \ \hat{\mu}_{\mathcal{D}}+\hat{\mu}_{\mathcal{T}}+\hat{\mu}_{l}. \end{eqnarray} $

      (15)

      where l is the orbital excitation between the diquark and triquark. The magnetic moment formula of the pentaquark with $ (cq_1)(\bar{c}q_2q_3) $ in the diquark-triquark model is

      $ \begin{aligned}[b] \mu =& \langle\ \psi\ |\ \hat{\mu}_{\mathcal{D}}+\hat{\mu}_{\mathcal{T}}+\hat{\mu}_{l}\ |\ \psi\ \rangle= \sum_{S_z,l_z}\ \langle\ SS_z,ll_z|JJ_z\ \rangle^{2} \left \{ \mu_{l} l_z + \sum_{\widetilde{S}_{\mathcal{D}},\widetilde{S}_{\mathcal{T}}}\ \langle\ S_\mathcal{D} \widetilde{S}_{\mathcal{D}},S_\mathcal{T} \widetilde{S}_{\mathcal{T}}|SS_z\ \rangle^{2} \Bigg [ \widetilde{S}_{\mathcal{D}}\bigg(\mu_{c} + \mu_{q_1}\bigg )\right.\\ &+\left. \sum_{\widetilde{S}_{\bar{c}}}\ \langle\ S_{\bar{c}} \widetilde{S}_{\bar{c}},S_{r} \widetilde{S}_{\mathcal{T}}-\widetilde{S}_{\bar{c}}|S_{\mathcal{T}} \widetilde{S}_{\mathcal{T}}\rangle^{2}\bigg(g\mu_{\bar{c}}\widetilde{S}_{\bar{c}}+(\widetilde{S}_{\mathcal{T}}-\widetilde{S}_{\bar{c}})(\mu_{q_2}+\mu_{q_3})\bigg ) \Bigg ]\right \}. \end{aligned} $

      (16)

      where $ S_{\mathcal{D}} $, $ S_{\mathcal{T}} $, and $ S_{r} $ represent the diquark, triquark, and light diquark spin inside the triquark, respectively. The triquark masses are roughly the sum of the masses of the corresponding diquark and antiquark. The numerical results with isospin $ (I,I_3) = (1,0) $ and $ (I,I_3) = (0,0) $ are shown in Tables 9 and 10, respectively.

      $ 8_{1f} $: $ \frac{1}{\sqrt6}[({c}d)(\bar c\{us\})+({c}u)(\bar c\{ds\})]-\sqrt{\frac{2}{3}}({c}s)(\bar c\{ud\}) $
      $ ^{2}S_{\frac{1}{2}} $ ($ J^P={\frac{1}{2}}^{-} $)$ {^{4}S_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ ^{6}S_{\frac{5}{2}}^{-} $($ J^P={\frac{5}{2}}^{-} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes0^{+} $
      $ (0,1,0) $0.522−0.0780.0510.6660.1780.1880.352
      $ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,1,0) $−0.1370.0580.0150.0800.3540.088
      $ {^{2}P_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{+}} $)$ {^{4}P_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{+}} $)$ {^{6}P_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{5}{2}}\otimes1^{-} $
      $ (0,1,0) $0.577−0.0300.0980.1520.5080.1570.242
      $ {^{4}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{7}{2}}} $ ($ {J^P={\frac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{5}{2}}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes1^{-} $
      $ (0,1,0) $0.7140.2330.2360.2990.370
      $ 8_{2f} $: $ \frac{1}{\sqrt2}\{ ({c}d)(\bar c[us])+({c}u)(\bar c[ds]) \} $
      $ ^2S_{\frac{1}{2}} $($ J^P={\frac{1}{2}}^{-} $)$ ^{4}S{{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ {^{2}P_{\frac{1}{2}}} $($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,1,0) $−0.3770.6870.4650.199−0.1840.235
      $ ^{2}P_{\frac{3}{2}} $ ($ J^P={\frac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $ ($ J^P={\frac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $ ($ {J^P={\frac{5}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes1^{-} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes1^{-} $
      $ (0,1,0) $−0.3070.8030.3810.558

      Table 9.  Magnetic moments of pentaquark states in the diquark-triquark model with the wave function$ \frac{1}{\sqrt6}[({c}d)(\bar c\{us\})+({c}u)(\bar c\{ds\})]-\sqrt{\frac{2}{3}}({c}s)(\bar c\{ud\}) $ in $ 8_{1f} $ and $ \frac{1}{\sqrt2}\{ ({c}d)(\bar c[us])+({c}u)(\bar c[ds]) \} $ in $ 8_{2f} $ with isospin $ (I,I_3) = (1,0) $. They are in the $ 8_{1f} $ representation from $ 6_f \otimes 3_f = 10_f \oplus 8_{1f} $ and the $ 8_{2f} $ representation from $ \bar{3}_f \otimes 3_f = 1_f \oplus8_{2f} $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}} $ correspond to the angular momentum and parity of the triquark, diquark, and orbital, respectively. The unit is proton magnetic moments.

      $ 8_{1f} $: $ \frac{1}{\sqrt2}[({c}u)(\bar c\{ds\})-({c}d)(\bar c\{us\})] $
      $ ^{2}S_{\frac{1}{2}} $($ J^P={\frac{1}{2}}^{-} $)$ {^{4}S_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ ^{6}S_{\frac{5}{2}}^{-} $($ J^P={\frac{5}{2}}^{-} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes0^{+} $
      $ (0,0,0) $0.0330.574−0.6010.910−0.555−0.0560.352
      $ {^{2}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $ ($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,0,0) $0.062−0.1260.2650.473−0.345−0.064
      $ {^{2}P_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{+}} $)$ {^{4}P_{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{+}} $)$ {^{6}P_{\frac{3}{2}}} $ ($ {J^P={\frac{3}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{5}{2}}\otimes1^{-} $
      $ (0,0,0) $0.1430.671−0.5030.707−0.363−0.0020.212
      $ {^{4}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{5}{2}}} $ ($ {J^P={\frac{5}{2}}^{+}} $)$ {^{6}P_{\frac{7}{2}}} $ ($ {J^P={\frac{7}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ [{\frac{3}{2}}^{-}\otimes1^{+}]_{\frac{5}{2}}\otimes1^{-} $$ {\frac{3}{2}}^{-}\otimes1^{+}\otimes1^{-} $
      $ (0,0,0) $1.008−0.4450.0410.3130.420
      $ 8_{2f} $: $ \frac{1}{\sqrt6}\{({c}d)(\bar c[us])-({ c}u)(\bar c[ds])-2( c s)(\bar c[ud])\} $
      $ ^2S_{\frac{1}{2}} $($ J^P={\frac{1}{2}}^{-} $)$ ^{4}S{{\frac{3}{2}}} $($ {J^P={\frac{3}{2}}^{-}} $)$ {^{2}P_{\frac{1}{2}}} $($ {J^P={\frac{1}{2}}^{+}} $)$ {^{4}P_{\frac{1}{2}}} $($ {J^P={\frac{1}{2}}^{+}} $)
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{1}{2}}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $
      $ (0,0,0) $−0.3770.223−0.2310.164−0.035−0.165
      $ ^{2}P_{\frac{3}{2}} $ ($ J^P={\frac{3}{2}}^{+} $)$ ^{4}P_{\frac{3}{2}} $ ($ J^P={\frac{3}{2}}^{+} $)$ {^{4}P_{\frac{5}{2}}^{+}} $($ {J^P={\frac{5}{2}}^{+}} $
      $ (Y, I, I_3) $$ {\frac{1}{2}}^{-}\otimes0^{+}\otimes1^{-} $$ [{\frac{1}{2}}^{-}\otimes1^{+}]_{\frac{3}{2}}\otimes1^{-} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes1^{-} $$ {\frac{1}{2}}^{-}\otimes1^{+}\otimes1^{-} $
      $ (0,0,0) $−0.3590.293−0.165−0.196

      Table 10.  Magnetic moments of pentaquark states in the diquark-triquark model with the wave function$ \frac{1}{\sqrt2}[({c}u)(\bar c\{ds\})-({c}d)(\bar c\{us\})] $ in $ 8_{1f} $ and $ \frac{1}{\sqrt6}\{({c}d)(\bar c[us])-({ c}u)(\bar c[ds])-2( c s)(\bar c[ud])\} $ in $ 8_{2f} $ with isospin $ (I,I_3) = (0,0) $. On the third line, $ J_{1}^{P_{1}}\otimes J_{2}^{P_{2}}\otimes J_{3}^{P_{3}} $ correspond to the angular momentum and parity of the triquark, diquark, and orbital, respectively. The unit is proton magnetic moments.

      The magnetic moments of $ P_{cs}(4459) $ in three configurations are compared, as shown in Table 11. The magnetic moments and numerical results illustrate that the molecular model is distinguishable from the other two models with $ 0({\dfrac{1}{2}}^{-}) $ but is indistinguishable with $ 0({\dfrac{3}{2}}^{-}) $. The diquark-diquark-antiquark and diquark-triquark models are completely indistinguishable with $ 0({\dfrac{1}{2}}^{-}) $ and $ 0({\dfrac{3}{2}}^{-}) $. In addition, the magnetic moments of $ P_{cs}(4459) $ have been studied in other papers. In Ref. [44], the numerical value in the molecular model was obtained as $ \mu_{P_{cs}} = -0.062\mu_{N} $ with 0($ {\dfrac{1}{2}}^{-} $) and $ \mu_{P_{cs}} = 0.465\mu_{N} $ with 0($ {\dfrac{3}{2}}^{-} $). In Ref., the magnetic dipole moments of $ P_{cs}(4459) $ in the molecular and diquark-diquark-antiquark models were extracted as $ \mu_{P_{cs}} = 1.75\mu_{N} $ and $ \mu_{P_{cs}}=0.34\mu_{N} $, respectively. These numerical results differ from our results of $ \mu_{P_{cs}} = -0.531\mu_{N} $ with 0($ {\dfrac{1}{2}}^{-} $) and $ \mu_{P_{cs}} = -0.231\mu_{N} $ with 0($ {\dfrac{3}{2}}^{-} $) in the molecular model and $ \mu_{P_{cs}}=0.223\mu_{N} $ in the diquark-diquark-antiquark model because of the wavefunction and quark mass. We compare the results in Table 12.

      $ P_{cs}(4459) $MultipletSpin-orbit coupling$ I(J^P) $Magnetic momentNumerical results
      Molecular model$ 8_{2f} $$ {\dfrac{1}{2}}^{+}\otimes1^{-}\otimes0^{+} $$0({\dfrac{1}{2} }^{-})$$ \dfrac{1}{9}(6\mu_{\bar{c}}-3\mu_{c}+\mu_{u}+\mu_{d}+4\mu_{s}) $−0.531
      $ 0({\dfrac{3}{2}}^{-}) $$ \dfrac{1}{6}(6\mu_{c}+6\mu_{\bar{c}}+\mu_{u}+\mu_{d}+4\mu_{s}) $−0.231
      Diquark-diquark-antiquark model$ 8_{2f} $$1^{+}\otimes0^{+}\otimes{\dfrac{1}{2} }^{-}\otimes0^{+}$$ 0({\dfrac{1}{2}}^{-}) $$ \dfrac{1}{9}(6\mu_{c}-3\mu_{\bar{c}}+\mu_{u}+\mu_{d}+4\mu_{s}) $0.223
      $ 0({\dfrac{3}{2}}^{-}) $$ \dfrac{1}{6}(6\mu_{c}+6\mu_{\bar{c}}+\mu_{u}+\mu_{d}+4\mu_{s}) $−0.231
      Diquark-triquark model$ 8_{2f} $$ {\dfrac{1}{2}}^{-}\otimes1^{+}\otimes0^{+} $$ 0({\dfrac{1}{2}}^{-}) $$ \dfrac{1}{9}(6\mu_{c}-3\mu_{\bar{c}}+\mu_{u}+\mu_{d}+4\mu_{s}) $0.223
      $ 0({\dfrac{3}{2}}^{-}) $$ \dfrac{1}{6}(6\mu_{c}+6\mu_{\bar{c}}+\mu_{u}+\mu_{d}+4\mu_{s}) $−0.231

      Table 11.  Magnetic moments of $ P_{cs}(4459) $ in the molecular, diquark-diquark-antiquark, and diquark-triquark models in the $ 8_{2f} $ representation with isospin $ (I,I_3) = (0,0) $.

      CasesABC
      $ J^P $$ {\dfrac{1}{2}}^{-} $$ {\dfrac{3}{2}}^{-} $$ {\dfrac{1}{2}}^{-} $$ {\dfrac{3}{2}}^{-} $$ {\dfrac{1}{2}}^{-} $$ {\dfrac{3}{2}}^{-} $
      Our results−0.531−0.2310.223−0.2310.223−0.231
      Ref. [44]−0.0620.465
      Ref. 1.750.34

      Table 12.  Our results and other theoretical results for the magnetic moments of $ P_{cs}(4459) $.The unit is proton magnetic moments. A, B, and C correspond to the molecular, diquark-diquark-antiquark, and diquark-triquark models.

    V.   SUMMARY
    • Inspired by the recently observed $ P_{cs}(4459) $, we systematically calculate the magnetic moments of $ P_{cs} $ with $ J^{P}={\dfrac{1}{2}}^{\pm}, {\dfrac{3}{2}}^{\pm}, {\dfrac{5}{2}}^{\pm} $, and $ {\dfrac{7}{2}}^{+} $ in three models: the molecular, diquark-diquark-antiquark, and diquark-triquark models. Comparing the numerical results of the above three models, we observe that the magnetic moments of states with the same quantum numbers are different. Indeed, even within the same model, magnetic moments with different configurations are different. We then compare the magnetic moments of $ P_{cs}(4459) $ in three configurations, which have been predicted to involve an S-wave state with $ I(J^P)=0({\dfrac{1}{2}}^{-}) $ and $ I(J^P)=0({\dfrac{3}{2}}^{-}) $. The results show that the molecular model is different from the other two models with $ I(J^P)=0({\dfrac{1}{2}}^{-}) $. These findings highlight that magnetic moments are helpful in determining internal structures when experimental data on $ P_{cs} $ keeps accumulating, because magnetic moments encode information about the charge distributions.

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