Neptunium incorporation into uranyl compounds that form as alteration products of spent nuclear fuel: Implications for geologic repository performance

Summary

Alteration of spent nuclear fuel in a geological repository under oxidizing conditions is likely to result in abundant uranyl compounds. Incorporation of radionuclides into the uranyl alteration phases may significantly reduce their mobility, thereby impacting repository performance. The following compounds have been synthesized from solutions containing from ∼10 to 500ppm Np⁵⁺: meta-schoepite, UO₃·2H₂O; Na-compreignacite, Na₂[(UO₂)₃O₂(OH)₃]₂(H₂O)₇; uranophane, Ca(UO₂)₂(SiO₃OH)₂(H₂O)₅; and β-(UO₂)(OH)₂. The structures of each involve sheets of uranyl polyhedra; the interlayers contain cations and H₂O groups in Na-compreignacite and uranophane, only H₂O in meta-schoepite, and β-(UO₂)(OH)₂ does not contain interlayer constituents. Synthesized powders were characterized by X-ray powder diffractometry, and were analyzed by ICP-AES (U, Na, Ca) and ICP-MS (Np). Aliquots of the powders were washed in 0.5M acetic acid to remove sorbed Np prior to analysis. The powders of meta-schoepite and β-(UO₂)(OH)₂ contained at most a few ppm Np⁵⁺. In contrast, powders of Na-compreignacite and uranophane contained Np⁵⁺ in proportion to the Np⁵⁺ concentration in the mother solution, and powders of each containing more than 400ppm Np⁵⁺ (of total Np + U) were obtained. Incorporation of Np⁵⁺ into uranyl compounds that form in a geological repository appears possible, and may impact the mobility of Np.