Nuclear moments of germanium isotopes near N=40

A Kanellakopoulos ,H Heylen ,Anastasia Borschevsky ,L V Rodríguez ,Klaus Blaum ,Tim Ratajczyk ,Á Koszorús ,C S Devlin ,W Nörtershäuser ,J Billowes ,Kristian König ,Z Y Xu ,S Sels ,S Lechner ,S Kaufmann ,R F García Ruíz ,Bai Shi-Wei ,Liang Xie ,R Neugart ,M L Bissell ,S Malbrunot-Ettenauer ,M L Reitsma ,S J Wang ,X F Yang ,G Neyens ,B Cheal ,Deyan T Yordanov

doi:10.1103/physrevc.102.054331

Abstract

Collinear laser spectroscopy measurements were performed on $^{69,71,73}$Ge isotopes ($Z = 32$) at ISOLDE-CERN. The hyperfine structure of the $4s^2 4p^2 \, ^3P_1 \rightarrow 4s^2 4p 5s \, ^3P_1^o$ transition of the germanium atom was probed with laser light of 269 nm, produced by combining the frequency-mixing and frequency-doubling techniques. The hyperfine fields for both atomic levels were calculated using state-of-the-art atomic relativistic Fock-space coupled-cluster calculations. A new $^{73}$Ge quadrupole moment was determined from these calculations and previously measured precision hyperfine parameters, yielding $Q_{\rm s}$ = $-$0.198(4) b, in excellent agreement with the literature value from molecular calculations. The moments of $^{69}$Ge have been revised: $\mu$ = +0.920(5) $\mu_{N}$ and $Q_{\rm s}$= +0.114(8) b, and those of $^{71}$Ge have been confirmed. The experimental moments around $N = 40$ are interpreted with large-scale shell-model calculations using the JUN45 interaction, revealing rather mixed wave function configurations, although their $g$-factors are lying close to the effective single-particle values. Through a comparison with neighboring isotones, the structural change from the single-particle nature of nickel to deformation in germanium is further investigated around $N = 40$.

Highlights

Over the years, structural changes have been intensively investigated in the region between the semimagic 68Ni and the doubly magic 78Ni [1,2,3,4,5,6]
The germanium ions were accelerated to 50 keV, mass separated using the high-resolution isotope separator (HRS) and subsequently cooled and bunched in a gas-filled linear Paul trap (ISCOOL) [26]
The systematic analysis of the hfs of 69,71,73Ge isotopes obtained in this work requires a revision of the hyperfine constants for 69Ge, resulting in different magnetic and quadrupole moments

Summary

Introduction

Structural changes have been intensively investigated in the region between the semimagic 68Ni and the doubly magic 78Ni [1,2,3,4,5,6]. The nuclear properties of ground and isomeric states, such as spins, moments, and charge radii, have made significant contributions in elucidating the above-mentioned nuclear phenomena. This was achieved by laser spectroscopy measurements on the isotopic chains of nickel (Z = 28), copper (Z = 29), zinc (Z = 30), and gallium (Z = 31) [3,5,6,7,8,11,13,14,15,16,17,18]. Nuclear spins and magnetic dipole moments are sensitive probes of the single-particle nature or configuration mixing of the wave functions [5,6,8,11], while the electric quadrupole moment and charge radii tell us more about the nuclear shape and collectivity [3,13,14]

Methods

Results

Discussion

Conclusion