Deformation and cluster structures in 12C studied with configuration mixing using Skyrme interactions

Abstract

We report an investigation of the structure of 12C nucleus employing a newly developed configuration-mixing method. In the three-dimensional coordinate-space representation, we generate a number of Slater determinants with various correlated structures using the imaginary-time algorithm. We then diagonalize a many-body Hamiltonian with the Skyrme interaction in the space spanned by the Slater determinants with parity and angular momentum projections. Our calculation reasonably describes the ground and excited states of 12C nucleus, both for shell-model-like and cluster-like states. The excitation energies and transition strengths of the ground-state rotational band are well reproduced. Negative parity excited states, 11-, 21-, and 31-, are also reasonably described. The second and third 0+ states, 02+ and 03+, appear at around 8.8 MeV and 15 MeV, respectively. The 02+ state shows a structure consistent with former results of the α-cluster models, however, the calculated radius of the 02+ state is smaller than those calculations. The three-α linear-chain configuration dominates in the 03+ state.