Deformations in N = 14 isotones

Systematic analysis of deformations in neutron-rich N=14 isotones was done based on the method of antisymmetrized molecular dynamics. The property of the shape coexistence in {sup 28}Si, which is known to have the oblate ground state and the prolate excited states, was successfully described. The results suggest that the shape coexistence may occur also in neutron-rich N=14 nuclei as well as {sup 28}Si. It was found that the oblate neutron shapes are favored because of the spin-orbit force in most of N=14 isotones. Q moments and E2 transition strengths in the neutron-rich nuclei were discussed in relation to the intrinsic deformations, and a possible difference between the proton and neutron deformations in {sup 24}Ne was proposed.

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