Abstract:
The Sigma(c)(2800)+ and Lambda c(2940)+ states are among the most interesting and intriguing particles whose internal structures have not yet been elucidated. Inspired by this, the magnetic dipole moments of the Sigma(c)(2800)+ and Lambda c(2940)+ states with quantum numbers J P = 1 2 - and J P = 3 2 -, respectively, are analyzed in the framework of QCD lightcone sum rules, assuming that they have a molecule composed of a nucleon and a D(& lowast;) meson. The magnetic dipole moments are obtained as mu Sigma(c) = 0.26 +/- 0.05 mu N and mu+ c = -0.31 +/- 0.04 mu N . The magnetic dipole moment is the leading-order response of a bound system to a weak external magnetic field. It therefore offers an excellent platform to explore the inner organization of hadrons governed by the quark-gluon dynamics of QCD. Comparison of the findings of this analysis with future experimental results on the magnetic dipole moments of the Sigma(c)(2800)+ and Lambda c(2940)+ states may shed light on the nature and internal organization of these states. The electric quadrupole and magnetic octupole moments of the c(2940)+ states have also been calculated, and these values are determined to be Q+ c = (0.65 +/- 0.25) x 10-3 fm2 and O+ c = -(0.38 +/- 0.10) x 10-3 fm3, respectively. The values of the electric quadrupole and magnetic octupole moments show a non-spherical charge distribution. We hope that our estimates of the electromagnetic properties of the Sigma(c)(2800)+ and Lambda c(2940)+ states, together with the results of other theoretical studies of the spectroscopic parameters of these states, will be useful for their search in future experiments and will help us to define the exact internal structures of these states.