Magnetic and quadrupole moments of the Zc(4020)+, Zc(4050)+, and Zc(4600)+ states in the diquark-antidiquark picture

Abstract

The magnetic and quadrupole moments of the Zc(4020)+, Zc(4050)+ and Zc(4600)+ states are calculated within the QCD light-cone sum rules. The compact diquark-antidiquark interpolating currents and the distribution amplitudes of the on-shell photon are used to extract the magnetic and quadrupole moments of these states. The magnetic moments are acquired as μZc = 0.50 +0.22-0.22~μN, μZ1c=1.22 +0.34-0.32~μN, and μZ2c=2.40 +0.53-0.48~μN for the Zc(4020)+, Zc(4050)+ and Zc(4600)+ states, respectively. The magnetic moments evaluated for the Zc4020)+, Zc(4050)+ and Zc(4600)+ states are sufficiently large to be experimentally measurable. The magnetic moment is an excellent platform for studying the internal structure of hadrons governed by the quark-gluon dynamics of QCD because it is the leading-order response of a bound system to a weak external magnetic field. The quadrupole moment results are DZc=(0.20 +0.05-0.04) × 10-3~fm2 , DZc1=(0.57 +0.07-0.08) × 10-3~fm2 , and DZc2=(0.30 +0.05-0.04) × 10-3~fm2 for the Zc(4020)+, Zc(4050)+ and Zc(4600)+ states, respectively. We obtain a non-zero, but small, value for the quadrupole moments of the Zc states, which indicates a non-spherical charge distribution. The nature and internal structure of these states can be elucidated by comparing future experimental data on the magnetic and quadrupole moments of the Zc(4020)+, Zc(4050)+, and Zc(4600)+ states with the results of the present study.