Changes in the mean square charge radii of neutron-deficient europium isotopes measured by the laser ion source resonance ionization spectroscopy

For the production of radioactive ion beams by means of the ISOL (isotope separation on-line) method in which the nuclei of interest are stopped in a thick target, chemistry plays a crucial role. It serves to separate the nuclear reaction products in atomic or molecular form from the bulk target and to transfer them efficiently to an ion source. This article gives an overview of ISOLDE radiochemical methods where targets (liquid metals, solid metals, carbides and oxides) and ion sources are optimized with respect to efficiency, speed and chemical selectivity. Rather pure beams of non-metals and volatile metals can be obtained with a temperature-controlled transfer line acting as thermo-chromatograph. For less volatile metals the temperature of the target and ion source units needs to be kept as high as possible, but a selective ion source can be used: positive surface ionization for metals with ionization potentials below about 6 eV and the RILIS (resonance ionization laser ion source) technique for most other metals.

Download Full-text

Developments towards the delivery of selenium ion beams at ISOLDE

The European Physical Journal A ◽

10.1140/epja/i2019-12873-4 ◽

2019 ◽

Vol 55 (10) ◽

Cited By ~ 1

Author(s):

K. Chrysalidis ◽

J. Ballof ◽

Ch. E. Düllmann ◽

V. N. Fedosseev ◽

C. Granados ◽

...

Keyword(s):

Maximum Yield ◽

Target Material ◽

Ion Beams ◽

Ion Source ◽

Resonance Ionization ◽

Laser Ion Source ◽

On Line ◽

Ionization Scheme ◽

Ionization Methods ◽

Resonance Laser

Abstract. The production of selenium ion beams has been investigated at the CERN-ISOLDE facility via two different ionization methods. Whilst molecular selenium (SeCO) beams were produced at ISOLDE since the early 1990s, recent attempts at reliably reproducing these results have so far been unsuccessful. Here we report on tests of a step-wise resonance laser ionization scheme for atomic selenium using the ISOLDE Resonance Ionization Laser Ion Source (RILIS). For stable selenium an ionization efficiency of 1% was achieved. During the first on-line radioisotope production tests, a yield of $ \approx 2.4 \times 10^4$≈2.4×104 ions/μC was measured for 71Se+, using a ZrO2 target with an electron impact ion source. In parallel, an approach for extraction of molecular carbonyl selenide (SeCO) beams was tested. The same ion source and target material were used and a maximum yield of $ \approx 3.6\times 10^5$≈3.6×105 ions/μ C of 71SeCO+ was measured.

Download Full-text

Changes in the mean square charge radii and electromagnetic moments of neutron-deficient Bi isotopes

10.1063/1.4932255 ◽

2015 ◽

Author(s):

A. E. Barzakh ◽

L. Kh. Batist ◽

D. V. Fedorov ◽

V. S. Ivanov ◽

P. L. Molkanov ◽

...

Keyword(s):

Mean Square ◽

Electromagnetic Moments ◽

Charge Radii ◽

The Mean

Download Full-text

Charge radii of exotic potassium isotopes challenge nuclear theory and the magic character of N = 32

Nature Physics ◽

10.1038/s41567-020-01136-5 ◽

2021 ◽

Cited By ~ 1

Author(s):

Á. Koszorús ◽

X. F. Yang ◽

W. G. Jiang ◽

S. J. Novario ◽

S. W. Bai ◽

...

Keyword(s):

Density Functional ◽

Neutron Number ◽

Nucleon Nucleon ◽

Nuclear Size ◽

Resonance Ionization ◽

Resonance Ionization Spectroscopy ◽

Β Decay ◽

Nuclear Theory ◽

Charge Radii ◽

A Charge

AbstractNuclear charge radii are sensitive probes of different aspects of the nucleon–nucleon interaction and the bulk properties of nuclear matter, providing a stringent test and challenge for nuclear theory. Experimental evidence suggested a new magic neutron number at N = 32 (refs. 1–3) in the calcium region, whereas the unexpectedly large increases in the charge radii4,5 open new questions about the evolution of nuclear size in neutron-rich systems. By combining the collinear resonance ionization spectroscopy method with β-decay detection, we were able to extend charge radii measurements of potassium isotopes beyond N = 32. Here we provide a charge radius measurement of 52K. It does not show a signature of magic behaviour at N = 32 in potassium. The results are interpreted with two state-of-the-art nuclear theories. The coupled cluster theory reproduces the odd–even variations in charge radii but not the notable increase beyond N = 28. This rise is well captured by Fayans nuclear density functional theory, which, however, overestimates the odd–even staggering effect in charge radii. These findings highlight our limited understanding of the nuclear size of neutron-rich systems, and expose problems that are present in some of the best current models of nuclear theory.

Download Full-text