D. Ø. Eriksen, B. Ryningen, B. Schoultz, G. Salberg, R. H. Larsen
Algeta ASA, P.O.Box 54, NO-0411 Kjels?s, Norway.
Institute for Energy Technology, P.O.Box, NO-2027 Kjeller, Norway.
DOI: 10.4236/jasmi.2012.21007   PDF    HTML   XML   3,728 Downloads   6,946 Views   Citations

Abstract

In order to find a fast and reliable method for measurements of organic and aqueous liquid phases containing a- and b-emitters in mixtures we developed a method based on Liquid Scintillation Counting (LSC) using Quantulus Low Level Spectrometer. The use of low level LSC instead of g-spectroscopy allows reduced sample activity, shorter count rates and use of sample changer. This is of great advantage when many samples have to be measured during a short time period. The main nuclides of interest were ²²⁷Ac and ²²³Ra. ²²⁷Ac does not have any appropriate g-radiation, therefore measurements of the nuclei of interest must be based on a- and b-spectroscopy. In this study, it is shown that analyses of the radionuclidic purity of the liquid phases could be determined by a- and b-spectroscopy with Quantulus.

Keywords

Dipex; LSC; Ra-223; Ac-227; Spectroscopy; Quantulus

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1. Introduction

In radiopharmacy the purity of the species involved is extreemly high both concerning the radioactive and the chemical compounds. Thus, in therapeutic injection fluids there are almost no radioactive or chemical contaminants. As a part of their work on developing new anticancer therapeutic agents, Algeta ASA is extracting radium from actinium. Radium grows in as a daughter nuclide from actinium (through thorium) [1]. It is well known that such separation can be achieved by both ion-exchange [2,3] and solvent extraction [4]. References 1 and 2 represent prior art of separation of actinides and of radium from their decay products and also from most other elements. This work is a study of di-phosphonate extractant Dipex® supplied by Eichrom as a separation agent for radium and actinium. The main nuclides of interest were ²²⁷Ac, ²²⁷Th and ²²³Ra. The series of daughter nuclides is shown in Figure 1 [5], where also the 1.38%—branch [4] of α-radiation creating ²²³Fr is shown separately. ²²⁷Ac does not have any appropriate γ-radiation, therefore direct measurements must be based on its β-particles whereas the daughter nuclide ²²⁷Th could be measured by its α-particles. ²²⁷Ac can be discriminated from the β-emitting daughter nuclides by the energy. Both ²¹¹Pb and ²⁰⁷Tl have β-particles with maximum energy >1 MeV [5]. The time of measurements is important to make proper corrections for the decay of the chain of daughters. In order to find a fast and reliable method for measurements of the liquid phases containing α- and β-emitters in mixtures it was decided to develop a method based on Liquid Scintillation Counting (LSC) using Quantulus Low Level Spectrometer. The use of low level LSC instead of γ-spectroscopy allows reduced sample activity, shorter count rates and use of sample changer. This is of great advantage when many samples have to be measured during a short time period.

2. Experimental

In all samples the liquid scintillator cocktail UltimaGold AB made by Packard was used. Features of Quantulus were utilised, comprising Peak Shape Analysis (PSA) for separating α- and β-events, divisions of spectrum in low and high energy windows, and Spectral Quench Parameter (SQP) for control of quenching. γ-spectroscopy was used for qualitative calibration.

Working with α-activity it is an advantage to keep the volumes as small as possible. Thus, most of the extraction tests were performed with small volumes, i.e. 0.5 - 5 mL, of both aqueous and organic phases. To ensure that

all tests had equal and comparable mixing a rod stirrer in a small cylindrical vial, e.g. counting vial, was used since extraction funnels and manual shaking showed to be inaccurate. The two phases were stirred for three minutes before the sample was set to rest a few minutes until the two phases were separated. As chemical equilibrium was shown to be quickly obtained, three minutes was chosen as mixing time in all extraction and back-extraction (stripping) tests.

3. Results and Discussion

To enable α- and β-separation the PSA-parameter must be set manually. In Figure 2, the relative α- and β-activities as functions of the PSA-value is shown. It was a definite minimum of α’s in β’s and vice versa for PSA = 60. This value was therefore used throughout the tests. Also, the SQP versus counting efficiency was determined. However, all samples had SQP-values > 850 which was a region where the efficiency was constant. There was therefore no need for corrections to compare the results. It must be noted, however, that the SQP is a relative measure of the maximum energy of an induced Compton electron spectrum from an external γ-source, and is thus only a measure of the quenching of the β-spectra, not the α-spectra.

In Figure 3 γ-spectra of the aqueous and organic phases after extraction are shown. The organic phase is containing ²²⁷Th, whereas the aqueous phase is containing ²²³Ra and its daughter nuclides. As is seen, ²²⁷Ac has no appropriate γ-energies and cannot be determined. Included in the figure are two β-spectra showing ²²⁷Ac in the low energy region (organic phase) and ²²³Ra and its daughter nuclides in the high energy region (aqueous phase).

Figure 4 shows LSC-spectra after extraction with three different concentrations of Dipex in hexane, 0.008%, 0.2%, and 2.15% by volume, respectively. The aqueous phase was 3 M HCl in all cases. These spectra

Conflicts of Interest

The authors declare no conflicts of interest.

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