학술논문
Nuclear charge radii of germanium isotopes around $N$ = 40
Document Type
Working Paper
Author
Wang, S. J.; Kanellakopoulos, A.; Yang, X. F.; Bai, S. W.; Billowes, J.; Bissell, M. L.; Blaum, K.; Cheal, B.; Devlin, C. S.; Ruiz, R. F. Garcia; Han, J. Z.; Heylen, H.; Kaufmann, S.; Konig, K.; Koszorus, A.; Lechner, S.; Malbrunot-Ettenauer, S.; Nazarewicz, W.; Neugart, R.; Neyens, G.; Nortershauser, W.; Ratajczyk, T.; Reinhard, P. -G.; Rodrıguez, L. V.; Sels, S.; Xie, L.; Xu, Z. Y.; Yordanov, D. T.; Yu, Y. M.
Source
Subject
Language
Abstract
Collinear laser spectroscopy measurements were performed on $^{68-74}$Ge isotopes ($Z = 32$) at ISOLDE-CERN, by probing the $4s^2 4p^2 \, ^3\!P_1 \rightarrow 4s^2 4p 5s \, ^3\!P_1^o$ atomic transition (269~nm) of germanium. Nuclear charge radii are determined via the measured isotope shifts, revealing a larger local variation than the neighboring isotopic chains. Nuclear density functional theory with the Fayans functionals Fy($\Delta r$,HFB) and Fy(IVP), and the SV-min Skyrme describes the experimental data for the differential charge radii $\delta\langle r^{2} \rangle$ and charge radii $R_{\rm c}$ within the theoretical uncertainties. The observed large variation in the charge radii of germanium isotopes is better accounted for by theoretical models incorporating ground state quadrupole correlations. This suggests that the polarization effects due to pairing and deformation contribute to the observed large odd-even staggering in the charge radii of the Ge isotopic chain.
Comment: 6 pages,5 figures
Comment: 6 pages,5 figures