Organic and Aqueous Redox Speciation of Cu(III) Periodate Oxidized Transuranium Actinides

McCann, Kevin; Sinkov, Sergey I.; Lumetta, Gregg J.; Shafer, Jenifer C.

doi:10.1021/acs.iecr.7b04158

Cited by 10 publications

(8 citation statements)

References 35 publications

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“…A group actinide(VI) extraction seeks to oxidize U, Np, Pu, and Am to the 6+ oxidation state and extract all four actinides into an organic phase as their respective actinyl cations by a solvating ligand or by a cocrystallization method. [53][54][55][56][57][58][59][60] The primary challenge in the group actinide(VI) extraction concept is oxidizing americium(III) to the 6+ oxidation state. An Am(VI)/Am(III) redox potential of 1.68 V vs. SCE requires strong oxidizers to generate the americyl cation).…”

Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

“…Solvent extraction of AmO2 2+ oxidized by Cu 3+ periodate was demonstrated with DAAP and monoamide ligands. 56,58,59 Although separation by 1 M DAAP was achieved, short contact times less than 10 seconds were required. 56,58 Distribution values decreased with extended contact times.…”

Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

“…56,58,59 Although separation by 1 M DAAP was achieved, short contact times less than 10 seconds were required. 56,58 Distribution values decreased with extended contact times. The trend was observed both in NaBiO3 and Cu 3+ periodate oxidation schemes.…”

Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

“…Studies showed that upon contact AmO2 2+ began to reduce to less extractable species (AmO2 + and Am 3+ ). 58 The initial challenge to group actinide(VI) separations was to oxidize Am in molar nitric acid solutions required for liquid-liquid extraction process like PUREX. The ability to oxidize and extract americium(VI) in molar nitric acid has been demonstrated.…”

Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

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Chemical Understanding of Actinide Separations

Servis

McCann

et al. 2021

Encyclopedia of Inorganic and Bioinorganic Chemistry

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This article provides a broad overview of the separation processes used to isolate actinides and the experimentally and computationally determined chemical characteristics that define those separations. The redox chemistry of the actinides plays a pivotal role in both aqueous and pyrochemical processing separations. The nearoverlapping energies of the 6d and 5f orbitals in the light actinides allows for facile adjustment of actinide oxidation states, which is used in many established separation methods. In contrast, the stable, generally 3+oxidation states of the midand heavy actinides can make them difficult to separate from the similarly lanthanides(III). In aqueous separations, the tendency of the actinides to form anionic and neutral aqueous complexes with a variety of complexants (especially soft donors) is used to achieve high separation factors between chemically similar elements in both solid-liquid separations and liquid-liquid extraction. This selectivity can be further tuned through the use of specialized organic or solid phase ligands. Pyroprocessing separations utilize the unique redox behavior of the actinides to adjust their distribution between a molten salt electrolyte and either a solid electrode or molten metal phase. Atomic-level insights into the mechanisms underlying actinide separation processes, with the ultimate goal of predicting separation behavior, can be provided by electronic structure and statistical mechanicalbased calculation methods.

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Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

Section: 3) Actinide(vi) Extractionmentioning

confidence: 99%

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Chemical Understanding of Actinide Separations

Servis

McCann

et al. 2021

Encyclopedia of Inorganic and Bioinorganic Chemistry

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“…Am(VI) is difficult to generate given the high Am(IV/III) couple ( E 1/2 = 2.62 V vs SHE) . A variety of chemical oxidants have been developed for Am(III) oxidation, including persulfate, sodium bismuthate, , copper periodate, silver ions in conjunction with ozone, even noble gas compounds . From a fuel cycle prospective, many of these oxidants have drawbacks due to downstream complications such as in the case of persulfate, where the sulfate product inhibits vitrification of the waste, or engineering complications as in the design of a filtration step to remove insoluble sodium bismuthate.…”

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confidence: 99%

Photocatalytic Conversion of Am(III) to Am(VI) Using a TiO₂ Electrode

Sheridan

González-Moya

McLachlan

et al. 2021

ACS Appl. Energy Mater.

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Titanium−titania (Ti|TiO 2 ) nanostructured electrodes in 0.1 M HNO 3 solutions under UV-light illumination using a 375 nm LED and a 1.55 V vs SCE bias photoelectrochemically oxidize Am(III) to Am(VI) (Am VI O 2 2+). Oxidation occurs through photoelectrochemically generated adsorbed hydroxyl radicals (2.81 V vs SCE) and/or direct electron transfer between the excited-state electrode (E(TiO 2 VB *) = ca. 2.95 V vs SCE) and Am(III) (E(Am IV/III ) = 2.62 V). An electrochemically irreversible but chemically reversible electrochemical process at 1.60 V vs SCE is assigned to the one-electron Am(VI/V) couple. This system may be applied to used nuclear fuel reprocessing to separate actinides of concern (U, Np, Pu, and Am), where Am is the most significant challenge.

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