Simultaneous Separation of Actinium and Radium Isotopes from a Proton Irradiated Thorium Matrix

Tara Mastren; Valery Radchenko; Allison Owens; Roy Copping; Rose Boll; Justin R. Griswold; Saed Mirzadeh; Lance E. Wyant; Mark Brugh; Jonathan W. Engle; Francois M. Nortier; Eva R. Birnbaum; Kevin D. John; Michael E. Fassbender

doi:10.1038/s41598-017-08506-9

Scientific Reports (Aug 2017)

Simultaneous Separation of Actinium and Radium Isotopes from a Proton Irradiated Thorium Matrix

Tara Mastren,
Valery Radchenko,
Allison Owens,
Roy Copping,
Rose Boll,
Justin R. Griswold,
Saed Mirzadeh,
Lance E. Wyant,
Mark Brugh,
Jonathan W. Engle,
Francois M. Nortier,
Eva R. Birnbaum,
Kevin D. John,
Michael E. Fassbender

Affiliations

Tara Mastren: Chemistry Division, Los Alamos National Laboratory
Valery Radchenko: Chemistry Division, Los Alamos National Laboratory
Allison Owens: Nuclear Security and Isotope Technology Division, Oak Ridge National Laboratory
Roy Copping: Nuclear Security and Isotope Technology Division, Oak Ridge National Laboratory
Rose Boll: Nuclear Security and Isotope Technology Division, Oak Ridge National Laboratory
Justin R. Griswold: Nuclear Security and Isotope Technology Division, Oak Ridge National Laboratory
Saed Mirzadeh: Nuclear Security and Isotope Technology Division, Oak Ridge National Laboratory
Lance E. Wyant: Nuclear Security and Isotope Technology Division, Oak Ridge National Laboratory
Mark Brugh: Chemistry Division, Los Alamos National Laboratory
Jonathan W. Engle: Chemistry Division, Los Alamos National Laboratory
Francois M. Nortier: Chemistry Division, Los Alamos National Laboratory
Eva R. Birnbaum: Chemistry Division, Los Alamos National Laboratory
Kevin D. John: Chemistry Division, Los Alamos National Laboratory
Michael E. Fassbender: Chemistry Division, Los Alamos National Laboratory

DOI: https://doi.org/10.1038/s41598-017-08506-9
Journal volume & issue: Vol. 7, no. 1
pp. 1 – 7

Abstract

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Abstract A new method has been developed for the isolation of 223,224,225Ra, in high yield and purity, from a proton irradiated 232Th matrix. Herein we report an all-aqueous process using multiple solid-supported adsorption steps including a citrate chelation method developed to remove >99.9% of the barium contaminants by activity from the final radium product. A procedure involving the use of three columns in succession was developed, and the separation of 223,224,225Ra from the thorium matrix was obtained with an overall recovery yield of 91 ± 3%, average radiochemical purity of 99.9%, and production yields that correspond to physical yields based on previously measured excitation functions.

Published in Scientific Reports

ISSN: 2045-2322 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Medicine; Science
Website: https://www.nature.com/srep/

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