Argonne National Laboratory

Shape Coexistence in 68Ni and surrounding neutron-rich nuclei

October 6, 2017

The structure of neutron-rich nuclei in the vicinity of “doubly-magic” 68Ni has been the subject of much recent scrutiny once it was realized, on the one hand, that the subshell gap at neutron number N=40 might be rather small and, on the other, that particle-hole excitations might result in the presence of states associated with different nuclear shapes. A set of recent papers [1-3], combining data from fragmentation reactions at the NSCL with those from multi-nucleon transfer reactions at ATLAS, has resulted in an interpretation of the low-spin level structure of 66,68,70Ni (see Fig. 1) in terms triple shape coexistence. In Ni, for example, 3 families of levels coexist: one associated with the spherical ground state, another with the oblate-deformed 0+ level at 1604 keV and a third built on a prolate, 2511-keV excitation. The observations agree with the results of Monte Carlo shell-model calculations by the Tokyo group [4] which attribute the presence of prolate shapes with large deformation to the role of proton particle-hole excitations across the Z=28 shell gap combined with the shape-driving effects of neutrons occupying the g9/2 and d5/2 orbitals.  It is worth noting that the prolate excitation decreases drastically in energy with increasing neutron number, an effect that can be traced to the tensor component of the monopole interaction [5].


  1. F. Recchia et al., Phys. Rev. C 88, 011302(R) (2013).
  2. C.J.  Chiara et al., Phys. Rev. C 91, 044309 (2015).
  3. C.J. Prokop et al., Phys. Rev. Lett. submitted (2015).
  4. Y. Tsunoda et al., Phys. Rev C 89, 031301 (2014).
  5. T. Otsuka et al., Phys. Rev. Lett. 95, 232502 (2005) and 104, 012501 (2010).