Role of quadrupole deformation and continuum effects in the "island of inversion'' nuclei 28,29,31F

Abstract

The properties of nuclei in the ``island of inversion'' (IOI) around Z=10 and N=20 are the focus of current nuclear physics research. Recent studies showed that 28F has a negative-parity ground state (g.s.) and thus lies within the southern shore of the IOI, and 29F presents a halo structure in its g.s., but it is unclear which effects, such as deformation, shell evolution due to tensor forces, or couplings to the continuum, lead to this situation. We investigate the role of quadrupole deformation and continuum effects on the single-particle (s.p.) structure of 28,29,31F from a relativistic mean-field (RMF) approach, and show how both phenomena can lead to a negative-parity g.s. in 28F and halo structures in 29,31F. We solve the Dirac equation in the complex-momentum (Berggren) representation for a potential with quadrupole deformation at the first order obtained from RMF calculations using the NL3 interaction, and calculate the continuum level densities using the Green's function method. We extract s.p. energies and widths from the continuum level densities to construct Nilsson diagrams, and analyse the evolution of both the widths and occupation probabilities of relevant Nilsson orbitals in 28F and find that some amount of prolate deformation must be present. In addition, we calculate the density distributions for bound Nilsson orbitals near the Fermi surface in 29,31F and reveal that for a quadrupole deformation 0.3 ≤ β2 ≤ 0.45 (prolate), halo tails appear at large distances. We also demonstrate that while in the spherical case the pf shells are already inverted and close to the neutron emission threshold, a small amount of quadrupole deformation can reduce the gap between fp shells and increase the role of the continuum, ultimately leading to the negative parity in the g.s. of 28F and the halo structures in 29,31F.