Abstract
In order to explore the possible physical quantities for judging different structures of the newly observed resonance $d^*(2380)$, we study its electromagnetic form factors. In addition to the electric charge monopole $C0$, we calculate its electric quadrupole $E2$, magnetic dipole $M1$, and six-pole $M3$ form factors on the base of the realistic coupled $\Delta\Delta+CC$ channel $d^*$ wave function with both the $S$- and $D$-partial waves. The results show that the magnetic dipole moment and electric quadrupole deformation of $d^*$ are 7.602 and $2.53\times 10^{-2}~\rm{fm}^2$, respectively. The calculated magnetic dipole moment in the naive constituent quark model is also compared with the result of $D_{12}\pi$ picture. By comparing with partial results where the $d^*$ state is considered with a single $\Delta\Delta$ and with a $D_{12}\pi$ structures, we find that in addition to the charge distribution of $d^*(2380)$, the magnetic dipole moment and magnetic radius can be used to discriminate different structures of $d^*$. Moreover, a quite small electric quadrupole deformation indicates that $d^*$ is more inclined to an slightly oblate shape due to our compact hexaquark dominated structure of $d^*(2380)$.
Highlights
Since the dibaryon state was proposed more than 50 years ago, the existence of the dibaryon has become one of the hot topics in particle and nuclear physics
By comparing with partial results where the dà state is considered with a single ΔΔ and with a D12π structures, we find that in addition to the charge distribution of dÃ, the magnetic dipole moment and magnetic radius can be used to discriminate different structures of dÃ
In the naive constituent quark model (NCQM), it is known that the magnetic moments of the proton and neutron are about MN=mq ∼ 3 and −2MN=3mq ∼ −2, respectively
Summary
Since the dibaryon state was proposed more than 50 years ago, the existence of the dibaryon has become one of the hot topics in particle and nuclear physics. In order to understand the structure of dÃ, the spin-3 particle, except the charge distribution (namely, the charge monopole form factor C0) calculated in our previous paper [39], we are going to study the other lower rank form factors of dÃ, such as its electric quadrupole E2, magnetic dipole M1, and magnetic octupole M3 form factors, with a compact ΔΔ þ C8C8 coupled-channel structure on the base of our chiral SU(3) constituent quark model. We obtained the mass and corresponding wave function of dà with the proposed structure (refer to the Appendix for detail), and the partial widths in various double pion and single pion decay channels All these calculated results consist with the data measured by the CELSIUS/WASA and WASA@COSY Collaborations.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
