Speaker
Description
Mid-shell Cd nuclei were traditionally considered to be the best examples of vibrational nuclei. Recent studies that combined detailed $\gamma$-ray spectroscopy with sophisticated beyond-mean-field calculations had suggested [1,2] that the low-lying 0$^+$ states in $^{110,112}$Cd possessed prolate, triaxial, and oblate shapes with rotational-like bands built upon them. If confirmed, this would have major implications on structural interpretations of nuclei in the Z = 50 region, and perhaps beyond. Soon afterwards a similar picture was suggested for $^{106}$Cd [3,4].
The low-energy Coulomb-excitation technique represents an ideal tool to study nuclear deformation. It enables a direct determination of electromagnetic transition matrix elements between low-lying excited states including spectroscopic quadrupole moments and signs. Those can be further analysed in terms of quadrupole invariants [5] yielding model-independent information on shape parameters of individual states. This requires, however, extensive sets of high-precision experimental data.
A multi-faceted experimental program to ascertain the deformation of low-energy states in $^{110}$Cd has been initiated. We seek to firmly establish the shape of the first three lowest-lying 0$^+$ states through the use of the rotation-invariant sum rules for $E$2 transitions. Coulomb-excitation measurements were performed using various reaction partners: $^{14}$N and $^{32}$S beams with EAGLE at HIL UW (Warsaw, Poland) [6,7], $^{60}$Ni beam with AGATA at LNL (Legnaro, Italy) [8] and $^{110}$Cd beam on a $^{208}$Pb target with GRETINA at ANL (Argonne , USA). These measurements have been complemented by an experiment performed at TRIUMF-ISAC with the GRIFFIN spectrometer examining the decays of $^{110}$Ag/$^{110}$In that will provide high-precision data on $\gamma$-ray branching ratios and transition mixing ratios. First results on quadrupole deformation parameters for the 0$^+_1$ and 0$^+_2$ states, demonstrating non-axial character of the ground state in $^{110}$Cd, will be presented. These experimental findings will be discussed in the context of: (i) Symmetry-Conserving Configuration-Mixing approach [1,2] and, (ii) new calculations with the general quadrupole collective Bohr Hamiltonian model involving two variants of interactions: SLy4 and UNEDF0.
Future perspectives will be outlined, including a brief overview of Coulomb-excitation studies addressing shape coexistence in the Z ∼ 50 region within the experimental campaigns at HIL Warsaw and at LNL Legnaro.
References
[1] P. Garrett et al., Phys. Rev. Lett. 123 (2019) 142502.
[2] P. Garrett et al., Phys. Rev. C 101 (2020) 044302.
[3] M. Siciliano et al., Phys. Rev. C 104 (2021) 034320.
[4] D. Kalaydjieva , PhD thesis, Universite Paris-Saclay, 2023.
[5] K. Kumar et al., Phys. Rev. Lett. 28 (1972) 249.
[6] K. Wrzosek-Lipska et al., Acta Phys. Pol. B 51 (2020) 789.
[7] K. Wrzosek-Lipska et al., accepted to be published in Phys. Lett. B,
https://doi.org/10.1016/j.physletb.2026.140315
[8] I.Z. Piętka et al. , Acta Phys. Pol. B Proc. Suppl. 18 (2025) 2-A26.
| Contribution category | Experiment |
|---|---|
| Presenter status | Faculty/Staff |