Optical vibrational spectroscopic signatures related to U3O8 production processes

Jordan M. Roach, Andrew Miskowiec, Luther McDonald, Erik C. Abbott, Cody A. Nizinski, Ian J. Schwerdt, Tyler L. Spano

Research output: Contribution to journalArticlepeer-review

Abstract

Uranium ore concentrates are materials found early within the nuclear fuel cycle and contain high concentrations of uranium in an easily transported form, making the concentrates a likely target for illegal diversion. These concentrates are typically converted to U3O8 for further processing and, therefore, may lose specific physicochemical characteristics in determining the materials’ source and processing history. In this work, we explore the Raman spectra of eight oxide samples produced from various uranium ore concentrates and processing pathways to examine the presence of spectroscopic signatures relating to each sample's process history. Samples produced from amine extraction and dialkylphosphoric acid extraction processes show unique characteristics due to high concentrations of α-UO3, whereas samples calcinated from metallic diuranates do not form pure α-U3O8 because of metallic ion inclusions. Pure α-U3O8 oxide samples are obtained through calcination of ammonium diuranate, ammonium uranyl carbonate, and metastudtite intermediates. The Raman spectra of these oxide samples show close agreement with pristine α-U3O8 spectra. However, deviations from the pristine spectra are observed in the 300–460 cm−1 spectral range. These deviations are unique identifying signatures that were likely created by lasting effects from the process history. Spectral center of mass calculations indicate grouping of samples based on processing history.

Original languageEnglish
Article number155522
JournalJournal of Nuclear Materials
Volume604
DOIs
StatePublished - Jan 2025

Keywords

  • Nuclear forensics
  • Raman spectroscopy
  • Uranium ore concentrates (UOCs)
  • Uranium oxides

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