Intertwined effects of pairing and deformation on neutron halos in magnesium isotopes

Abstract

Matter radii of the 34-40Mg nuclei are investigated by self-consistent Hartree-Fock-Bogolyubov calculations assuming the axial symmetry. With the semi-realistic M3Y-P6 interaction, the N-dependence of the matter radii observed in the experiments is reproduced excellently. Both the pairing and the deformation play significant roles in an intertwined manner. The 35Mg nucleus has a smaller radius than the neighboring even-N nuclei, which is attributed to its smaller deformation. In contrast, a neutron halo is obtained in 37Mg. We point out that, in contrast to the pairing anti-halo effect that may operate on the even-N nuclei, the pair correlation enhances halos in odd-N nuclei, owing to the new mechanism which we call unpaired-particle haloing. The halo in 37Mg is predicted to have peanut shape in its intrinsic state, reflecting p-wave contribution, as in 40Mg. The N-dependence of the deformation is significant again, by which the single-particle level dominated by the p-wave component comes down.