# $\beta^-$ decay study of the $^{66}$Mn - $^{66}$Fe - $^{66}$Co -   $^{66}$Ni chain

**Authors:** M. Stryjczyk, Y. Tsunoda, I. G. Darby, H. De Witte, J. Diriken, D. V., Fedorov, V. N. Fedosseev, L. M. Fraile, M. Huyse, U. K\"oster, B. A. Marsh,, T. Otsuka, D. Pauwels, L. Popescu, D. Radulov, M. D. Seliverstov, A. M., Sj\"odin, P. Van den Bergh, P. Van Duppen, M. Venhart, W. B. Walters, K., Wimmer

arXiv: 1812.07510 · 2019-01-01

## TL;DR

This study investigates the beta decay of $^{66}$Mn to understand shell evolution and shape coexistence around $^{68}$Ni by measuring gamma transitions and comparing results with shell model calculations.

## Contribution

It provides new experimental data on gamma transitions and beta decay properties of nuclei in the $^{66}$Mn-$^{66}$Ni chain, and compares these with Monte Carlo Shell Model predictions.

## Key findings

- Spin and parity of $^{66}$Co ground state assigned as $1^+$.
- Observed beta decay feeding patterns differ from earlier studies.
- Shell model calculations successfully reproduce low-energy state properties.

## Abstract

Background: Shell evolution can impact the structure of the nuclei and lead to effects such as shape coexistence. The nuclei around $^{68}$Ni represent an excellent study case, however, spectroscopic information of the neutron-rich, $Z<28$ nuclei is limited. Purpose: The goal is to measure $\gamma$-ray transitions in $^{66}$Fe, $^{66}$Co and $^{66}$Ni populated in the $\beta^-$ decay of $^{66}$Mn, to determine absolute $\beta$-feedings and relative $\gamma$-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 $^{65,66}$Fe, $^{66}$Co and $^{66}$Ni were studied in the $\beta^-$ decay of $^{66}$Mn produced at ISOLDE, CERN. The beam was purified by means of laser resonance ionization and mass separation. The $\beta$ and $\gamma$ 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 $\beta$-decay half-lives of the nuclei. Results: The relative small $\beta$-decay ground state feeding of $^{66}$Fe obtained in this work is at variant to the earlier studies. Spin and parity $1^+$ was assigned to the $^{66}$Co ground state based on the strong ground state feeding in the decay of $^{66}$Fe as well as in the decay of $^{66}$Co. Experimental log(ft) values, $\gamma$-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 $^{66}$Mn to $^{66}$Ni chain were proposed. Conclusions: The $\beta$-decay chain starting $^{66}$Mn towards $^{66}$Ni, crossing $N=40$, evolves from deformed nuclei to sphericity...

## Full text

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## Figures

24 figures with captions in the complete paper: https://tomesphere.com/paper/1812.07510/full.md

## References

100 references — full list in the complete paper: https://tomesphere.com/paper/1812.07510/full.md

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Source: https://tomesphere.com/paper/1812.07510