β- decay study of the 66Mn - 66Fe - 66Co - 66Ni chain

Abstract

Background: Shell evolution can impact the structure of the nuclei and lead to effects such as shape coexistence. The nuclei around 68Ni represent an excellent study case, however, spectroscopic information of the neutron-rich, Z<28 nuclei is limited. Purpose: The goal is to measure γ-ray transitions in 66Fe, 66Co and 66Ni populated in the β- decay of 66Mn, to determine absolute β-feedings and relative γ-decay probabilities and to compare the results with Monte Carlo Shell Model calculations in order to study the influence of the relevant single neutron and proton orbitals occupancies around Z=28 and N=40. Method: The low-energy structures of 65,66Fe, 66Co and 66Ni were studied in the β- decay of 66Mn produced at ISOLDE, CERN. The beam was purified by means of laser resonance ionization and mass separation. The β and γ events detected by three plastic scintillators and two MiniBall cluster germanium detectors, respectively, were correlated in time to build the low-energy excitation schemes and to determine the β-decay half-lives of the nuclei. Results: The relative small β-decay ground state feeding of 66Fe obtained in this work is at variant to the earlier studies. Spin and parity 1+ was assigned to the 66Co ground state based on the strong ground state feeding in the decay of 66Fe as well as in the decay of 66Co. Experimental log(ft) values, γ-ray deexcitation patterns and energies of excited states were compared to Monte Carlo Shell Model calculations. Based on this comparison, spin and parity assignments for the selected number of low-lying states in the 66Mn to 66Ni chain were proposed. Conclusions: The β-decay chain starting 66Mn towards 66Ni, crossing N=40, evolves from deformed nuclei to sphericity...