A modified solvent has been developed at Oak Ridge National laboratory (ORNL) for a caustic-side solvent extraction (CSSX) process that removes cesium (Cs) from Savannah River Site (SRS) tank waste. The modified solvent was evaluated using the same CSSX flowsheet, SRS simulant, and 33-stage minicontactor (2-cm centrifugal contactor) that had been used to test the previous CSSX solvent. As with the previous solvent, the key process goals were achieved: (1) the Cs was removed from the waste with decontamination factors greater than 40,000 and (2) the recovered Cs was concentrated by a factor of 15 in dilute nitric acid. Thus, the modified CSSX solvent can be used in place of the previous solvent while maintaining satisfactory hydraulic performance and still achieving process requirements at the bench scale.
The TRUEX (TRansUranic Extraction) solvent extraction process was developed at Argonne National Laboratory (ANL) for the Department of Energy. A TRUEX demonstration completed at ANL involved the processing of analytical and experimental waste generated there and at the New Brunswick Laboratory. A 20-stage centrifugal contactor was used to recover plutonium, americium, and uranium from the waste. Approximately 84 g of plutonium, 18 g of uranium, and 0.2 g of americium were recovered from about 118 L of solution during four process runs. Alpha decontamination factors as high as 65,000 were attained, which was especially important because it allowed the disposal of the process rafPinate as a lowlevel waste. The recovered plutonium and uranium were converted to oxide; the recovered americium solution was concentrated by evaporation to approximately 100 mL. * Thc TRU limit for waste is I00 nCi/g; our 10 nCi/mL limit is well below this limit. * This volume includes the sodium hydroxide that was added to the raffinate after TRUEX processing to adjust the pH to 6-9.
As part of the U.S. nonproliferation effort, we are investigating the conversion of the production
of fission-product 99Mo from use of high-enriched uranium (HEU) to low-enriched uranium (LEU).
Successful conversion from HEU to LEU (<20% 235U) requires an irradiation target that contains
5 times more uranium but minimizes changes to target geometry and processing. The LEU target
being developed uses thin foils of uranium metal that can be removed from the target hardware
for dissolution and processing. This paper describes our recent successes in target fabrication,
irradiation, and processing. Target fabrication has been improved by (1) heat-treating the
uranium foil to produce a random, small-grain structure and (2) electrodepositing zinc and nickel
fission-fragment barriers onto the foil. These fission-fragment barriers have been found to be
stable during transport of the targets following irradiation. Recent irradiation tests have shown
that the concept is sound. Progress was also made in broadening international cooperation in
our development activities.
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