Litcius/Paper detail

Neptunium extraction by <i>N</i>,<i>N</i>-dialkylamides

Jarrod M. Gogolski, Peter R. Zalupski, Travis S. Grimes, Mark P. Jensen

2020Radiochimica Acta13 citationsDOIOpen Access PDF

Abstract

Abstract Separation of neptunium by solvent extraction has been based on tributylphosphate (TBP) for decades, but TBP is not fully incinerable, which adds to the burden of long-lived radioactive waste. Alternatives to TBP for uranium and plutonium extraction, such as the N , N -diakylamides, previously have been explored in the hopes of transitioning to an extractant that is incinerable. Four N , N -diakylamides, N , N -dihexylhexanamide (DHHA), N , N -dihexyloctanamide (DHOA), N , N -di(2-ethylhexyl)butanamide (DEHBA), and N , N -di(2-ethylhexyl)-iso-butanamide (DEHiBA) were considered in this work for their potential to extract millimolar concentrations of Np(IV), Np(V), and Np(VI) from nitric acid solutions into organic solutions containing 1 M extractant in Exxsol D60. Under these conditions the branching of the alkyl substituents affects the extractability of Np(VI) and Np(IV), causing three of the dialkylamides, DHHA, DHOA and DEHBA, to extract neptunium in the expected order Np(VI) &gt; Np(IV) &gt; &gt; Np(V). In contrast, branched DEHiBA is so poor an extractant for Np(IV) that the extraction order becomes Np(VI) &gt; &gt; Np(V) &gt; Np(IV) between 0.1 and 5.6 M HNO 3 due to partial oxidation of the Np(V) in nitric acid.

Topics & Concepts

NeptuniumChemistryNitric acidExtraction (chemistry)Nuclear chemistrySolvent extractionUraniumPlutoniumRadiochemistryInorganic chemistryChromatographyMetallurgyMaterials scienceRadioactive element chemistry and processingNuclear materials and radiation effectsNuclear Materials and Properties