July 31, 2024
Journal Article

Oxygen Isotope and Fluorine Impurity Signatures During Conversion of Uranium Ore Concentrates to Nuclear Fuel

Abstract

Within the front end of the nuclear fuel cycle, many processes impart forensic signatures. Oxygen stable isotopes (d18O values) of uranium bearing materials have been theorized to provide processing and geolocational signatures of interdicted materials. However, this signature has found minimal utility due to a limited understanding of how oxygen isotopes are influenced during uranium processing. This study explores oxygen isotope exchange and fractionate between magnesium diuranate (MDU), ammonium diuranate (ADU), and uranyl fluoride (UO2F2) with steam (water vapor) during their reduction to UOx. The MDU was precipitated from two water sources, one enriched and one depleted in 18O. The UO2F2 was precipitated from a single water source and either directly reduced or converted to ADU prior to reduction. All MDU, ADU, and UO2F2 were reduced to UOx in a 10% hydrogen/90% nitrogen atmosphere that was dry or included steam. Powder X-ray diffraction (p-XRD) was used to verify the composition of materials after reduction as mixtures of primarily U3O8, U4O9, and UO2 with trace magnesium and fluorine phases in the UOx from MDU and UO2F2, respectively. The bulk oxygen isotope composition of UOx from MDU was analyzed using fluorination to remove the lattice-bound oxygen, and then O2 was subsequently analyzed with isotope ratio mass spectrometry (IRMS). The oxygen isotope compositions of the ADU, UO2F2, and the resulting UOx were analyzed by large geometry secondary ion mass spectrometry (LG-SIMS). When reduced with steam, the MDU, ADU, and UO2F2 experienced significant oxygen isotope exchange, and the resulting d18O values of the UOx approached the values of the steam. When reduced without steam, the d18O values of the UOx were similar to that of the starting materials, where comparisons could be made. LG-SIMS isotope mapping of F impurity abundances and distributions showed that direct steam-assisted reduction from UO2F2 significantly removed F impurities while dry reduction from UO2F2 led to the formation of UOx that was enhanced in F impurities. In addition, when UO2F2 was processed via precipitation to ADU and calcination to U3O8, F impurities were largely removed, and reductions to UOx with and without steam each had low F impurities. Overall, these findings show promise for combining multiple signatures to predict the process history during the conversion of uranium ore concentrates to nuclear fuel.

Published: July 31, 2024

Citation

Chalifoux A.M., C.A. Nizinski, M. Cisneros, T.J. Tenner, B. Naes, K.N. Wurth, and E. Oerter, et al. 2024. Oxygen Isotope and Fluorine Impurity Signatures During Conversion of Uranium Ore Concentrates to Nuclear Fuel. ACS Omega 9, no. 10:12135–12145. PNNL-SA-192129. doi:10.1021/acsomega.3c10481

Research topics