Nuclear resonance fluorescence as a complementary probe of triple shape coexistence in ⁶⁴Ni

A recent study of 64Ni [1], which combined four complementary experimental techniques, revealed three coexisting shapes, extended shape coexistence first observed in the neutron-rich nickel isotopes to the heaviest stable one, and agreed with Monte-Carlo shell-model (MCSM) calculations. The stability of 64Ni facilitates experiments with nuclear resonance fluorescence and can shed additional light on this nucleus [2].

With the polarized, quasi-monoenergetic photon beam from the HIγS facility [3], 64Ni excited states were populated at energies of 8.7 and 8.95 MeV, and their decays through levels at lower excitation energies were characterized. Specifically, the spins and parities of the observed states were firmly established through γγ-angular correlations. In addition to the excitation energies, and quantum numbers of newly observed levels, information on their decay branching and mixing ratios and lifetimes provide further tests of the MCSM predictions.

[1] N. Mărginean et al., Phys. Rev. Lett. 125, 10502 (2020)

[2] D. R. Little, PhD Thesis, UNC at Chapel Hill (2020)

[3] H. R. Weller et al., Prog. Part. Nucl. Phys. 62, 257 (2009)