Large-scale shell-model calculations for unnatural-parity high-spin states in neutron-rich Cr and Fe isotopes

Abstract

We investigate unnatural-parity high-spin states in neutron-rich Cr and Fe isotopes using large-scale shell-model calculations. These shell-model calculations are carried out within the model space of fp-shell + 0g9/2 + 1d5/2 orbits with the truncation allowing 1ω excitation of a neutron. The effective Hamiltonian consists of GXPF1Br for fp-shell orbits and V MU with a modification for the other parts. The present shell-model calculations can describe and predict the energy levels of both natural- and unnatural-parity states up to the high-spin states in Cr and Fe isotopes with N35. The total energy surfaces present the prolate deformations on the whole and indicate that the excitation of one neutron into the 0g9/2 orbit plays the role of enhancing the prolate deformation. For the positive(unnatural)-parity states in odd-mass Cr and Fe isotopes, their energy levels and prolate deformations indicate the decoupling limit of the particle-plus-rotor model. The sharp drop of the 9/21+ levels in going from N=29 to N=35 in odd-mass Cr and Fe isotopes is explained by the Fermi surface approaching the 0g9/2 orbit.