Radiative decay of c1 states in effective Lagrangian approach

Abstract

The c1(3872) state, first observed by the Belle collaboration with its quantum numbers identified as JPC = 1++, has been the subject of extensive research due to its intriguing properties. Several theoretical interpretations have been proposed to explain its unique characteristics, including the c1(2P) assignment, a molecular D*D/DD* configuration, a coupled-channel framework incorporating cc and di-meson degrees of freedom, and the compact tetraquark hypothesis. However, challenges remain in reconciling its mass coincidence with the threshold and the observed isospin violation within both the pure cc and compact tetraquark models. In this study, we examine the radiative decays of the c1(1P) and c1(3872) states in an effective field theory framework, incorporating triangle loops of D and D* mesons. The model parameters are calibrated based on the observed branching fraction of the radiative decay mode c1(1P) J/ γ. Utilizing these fixed parameters, we predict the branching fractions R_c1(3872) J/ γ 10-1 and R_c1(3872) (2S) γ 10-2, and the relative fraction Rγ ≈ 0.109. The work supports the argument that the c1(3872) is unlikely a cc state.