The doubly-charmed pentaquark in a quark model with a complete set of harmonic oscillator bases

Abstract

As our recent quark model calculation~Noh:2023fdy suggests a strong possibility of a compact Tcc that closely reproduces experimental mass, we have a strong incentive to extend our work to investigate the possible compact configuration of a pentaquark udccs, which is related to the structure of the doubly charmed tetraquark Tcc. Since the introduction of a complete set of 3-dimensional harmonic oscillator bases to a spatial wave function in solving a quark model-based Hamiltonian with variational method leads to a more accurate value of the mass, it seems natural that future studies of the pentaquark should be treated with the same elaborate technical approach. To attain such precision for the ground state energy, we utilize a complete set of 3-dimensional harmonic oscillator base up to 6th quanta. Before carrying out this process, one important thing that has to be taken into account is to find out the color spin states of the pentaquark for the evaluation of color and spin interaction most essential to the quark model configuration. To easily identify the suitable configuration, we make a systematic analysis of SU(6)CS irreducible representation of the pentaquark, from which we find that there is a correspondence between the color spin states obtained from their coupling scheme and the multiplet of the SU(6)CS irreducible representation of the pentaquark. We find that the energy of the pentaquark configuration is +18.5 MeV above the lowest threshold for decay into cc and K, suggesting that this configuration is not stable against its decay. Nonetheless, while we used a Gaussian hyperfine potential, it was recently found that a Yukawa form leads to a stronger attraction for the Tcc configuration. Therefore it is important to study the same configuration using the latter potential.