Journal
SOLVENT EXTRACTION AND ION EXCHANGE
Volume 39, Issue 3, Pages 305-327Publisher
TAYLOR & FRANCIS INC
DOI: 10.1080/07366299.2020.1834979
Keywords
TBP; technetium; rhenium; uranium; solvent extraction; speciation; DFT; XANES; EXAFS; modeling
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This study focuses on the extraction mechanism of technetium with TBP in the PUREX process, with a particular emphasis on the structure of the uranium-technetium complex. The research reveals the existence of (HTcO4)(TBP)(n) and mixed UO2(NO3)(TcO4)(HNO3)(x)(TBP)(n) complexes in the organic phase. Through thermodynamic modeling and spectroscopic techniques, comprehensive characterization of uranium-technetium and uranium-rhenium mixed species can be achieved.
Among the fission products present in the spent nuclear fuel, technetium exhibits a singular behavior in reprocessing operations performed by solvent extraction. Indeed, this strong acid readily dissociates to form the oxo-anion TcO4 (-) that may interfere with uranium(VI), plutonium(IV), and zirconium(IV) in the extraction cycles of the PUREX process. This paper focuses on the uranium-technetium complex with TBP and on its non-radioactive rhenium surrogate. Despite the large set of distribution data available for rhenium and technetium extraction with TBP, the structures of the co-extracted complexes remain largely unknown. However, it is important to understand clearly the extraction mechanism of technetium with TBP in the PUREX process to optimize the separation process and to model its behavior during the extraction steps. Based on distribution data available in the literature, a thermodynamic model was developed for the extraction of technetium with TBP for a large excess of uranium(VI) in organic phase. A good representation of uranium and technetium distribution data was thus obtained when considering the formation of (HTcO4)(TBP)(n) complexes, as well as mixed UO2(NO3)(TcO4)(HNO3)(x)(TBP)(n), complexes. In the complex UO2(NO3)(2)(HNO3)(x)(TBP)(n)., one pertechnetate anion replaces one nitrate in the uranium coordination sphere. Combination of complementary spectroscopic techniques (FT-IR and X-ray absorption) supported by theoretical calculations (density functional theory) with organic phases containing a large excess of technetium(VII) or rhenium(VII) enabled full characterization of the limit mixed uranium-technetium species and also of mixed uranium-rhenium species. Details on the coordination of the uranium-technetium complex are provided with the help of DFT calculations and XAS measurements.
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