Aqueous Speciation of Tetravalent Actinides in the Presence of Chloride and Nitrate Ligands

Bhattacharjee, Rameswar; Miró, Pere

doi:10.1021/acs.inorgchem.2c02064

Cited by 5 publications

(6 citation statements)

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“…Both TcO 4 − and ReO 4 − ligate Zr/Hf IV invariably, splitting the common Zr 4 /Hf 4 flat tetramer ( Figure 1F) to yield a dihydroxide‐bridged dimer, exemplified in four isostructural compounds determined by single‐crystal X‐ray diffraction; M 2 (OH) 2 (XO 4 − ) 6 (H 2 O) 6 (M=Zr IV or Hf IV ; X=Re VII or Tc VII , referred to later as Zr 2 Re 6 , Hf 2 Re 6 , Zr 2 Tc 6 and Hf 2 Tc 6 ; see SI for synthesis details). This dimer was recently predicted by computation to be the first step of Zr/Hf‐hydrolysis, [27] but not observed in an isolated and soluble form, prior to this current study. The Zr/Hf‐dimers (Figure 1F) were synthesized two ways; 1) By dissolving corresponding Zr/Hf oxyhydroxide in perrhenic/pertechnic acid, or 2) By co‐dissolving the corresponding oxychloride salt (Zr 4 /Hf 4 ) with perrhenic/pertechnic acid, followed by slow evaporation to yield crystals (see SI for more details).…”

Section: Resultsmentioning

confidence: 45%

Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO₄ Co‐Mobility in the Nuclear Fuel Cycle

Shohel,

Bustos,

Roseborough

et al. 2023

Chemistry A European J

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Spent nuclear fuel contains heavy element fission products that must be separated for effective reprocessing for a safe and sustainable nuclear fuel cycle. 93Zr and 99Tc are high‐yield fission products that co‐transport in liquid‐liquid extraction processes. Here we seek atomic‐level information of this co‐extraction process, as well as fundamental knowledge about ZrIV (and HfIV) aqueous speciation in the presence of topology‐directing ligands such as pertechnetate (TcO4−) and non‐radioactive surrogate perrhenate (ReO4−). In this context, we show that the flat tetrameric oxyhydroxyl‐cluster [MIV4(OH)8(H2O)16]8+ (and related polymers) is dissociated by perrhenate/pertechnetate to yield isostructural dimers, M2(OH)2(XO4−)6(H2O)6 ⋅ 3H2O (M=Zr/HfIV; X=Re/TcVII), elucidated by single‐crystal X‐ray diffraction. We used these model compounds to understand the pervasive 93Zr‐99Tc coextraction with further speciation studies in water, nitric acid, and tetrabutylphosphate (TBP) ‐kerosene; where the latter two media are relevant to nuclear fuel reprocessing. SAXS (small angle X‐ray scattering), compositional evaluation, and where experimentally feasible, ESI‐MS (electrospray ionization mass spectrometry) showed that perrhenate/pertechnetate influence Zr/HfIV‐speciation in water. In Zr‐XO4 solvent extraction studies to simulate fuel reprocessing, we provide evidence that TcO4− enhances extraction of ZrIV, and compositional analysis of the extracted metal‐complexes (Zr‐ReO4 study) is consistent with the crystallized ZrIV2(OH)2(ReVIIO4−)6(H2O)6⋅dimer.

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Section: Resultsmentioning

confidence: 45%

Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO₄ Co‐Mobility in the Nuclear Fuel Cycle

Shohel,

Bustos,

Roseborough

et al. 2023

Chemistry A European J

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“…The cation geometry is a tricapped trigonal prism with a point group around the plutonium metal center of D 3 h with three outer-sphere nitrate ions. Solution-state and computational studies have shown the tendency for the hexanitrato species to complex with lanthanides and actinides. − Solid-state studies by Kawasaki et al have also shown that hexanitrato species with the Ln 3+ ions can form in their presence of DGA complexes . Additionally, solid-state actinide hexanitrato species have also been reported in crystal structures containing Th 4+ , U 4+ , Np 4+ , Pu 4+ , Am 3+ , and Cm 3+ ions. , These studies have shown that there is potential to isolate the hexanitrato species for plutonium TMDGA complexes.…”

Section: Resultsmentioning

confidence: 99%

Co-Crystallization of Plutonium(III) and Plutonium(IV) Diglycolamides with Pu(III) and Pu(IV) Hexanitrato Anions: A Route to Redox Variants of [Pu^III,IV(DGA)₃][Pu^III,IV(NO₃)₆]_x

Rotermund,

Sperling,

Horne

et al. 2023

Inorg. Chem.

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N,N,N′,N’-tetramethyl diglycolamide (TMDGA), a methylated variant of the diglycolamide extractants being proposed as curium holdback reagents in advanced used nuclear fuel reprocessing technologies, has been crystallized with plutonium, a transuranic actinide that has multiple accessible oxidation states. Two plutonium TMDGA complexes, [PuIII(TMDGA)3][PuIII(NO3)6] and[PuIV(TMDGA)3][PuIV(NO3)6]2·0.75MeOH, were crystallized through solvent diffusion of a reaction mixture containing plutonium(III) nitrate and TMDGA. The sample was then partially oxidized by air to yield [PuIV(TMDGA)3][PuIV(NO3)6]2·0.75MeOH. Single-crystal X-ray diffraction reveals that the multinuclear systems crystallize with hexanitrato anionic species, providing insight into the first solid-state isolation of the elusive trivalent plutonium hexanitrato species. Crystallography data show a change in geometry around the TMDGA metal center from Pu3+ to Pu4+, with the symmetry increasing approximately from C 4v to D 3h . These complexes provide a rare opportunity to investigate the bond metrics of plutonium in two different oxidation states with similar coordination environments. Further, these new structures provide insight into the potential chemical and structural differences arising from the radiation-induced formation of transient tetravalent curium oxidation states in used nuclear fuel reprocessing streams.

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“…The ligands used to bind the M 6 O 8 cores are usually selected in such a way to help control the hydrolysis process and stop the formation of larger number of metal center aggerates [26] . These ligands control the hydrolysis process by taking up part of the coordination spheres of each metal enter leaving limited possibility for further [OH] − coordination and bridging [27] .…”

Section: Resultsmentioning

confidence: 99%

“…[14,21] The ligands used to bind the M 6 O 8 cores are usually selected in such a way to help control the hydrolysis process and stop the formation of larger number of metal center aggerates. [26] These ligands control the hydrolysis process by taking up part of the coordination spheres of each metal enter leaving limited possibility for further [OH] À coordination and bridging. [27] Typically this approach utilizes bulky ligands that coordinate the metal centers in a bridging manner which limits the interactions with water while also acting as a unit to direct the formation of the M 6 O 8 core.…”

Section: Structural Characterizationmentioning

confidence: 99%

Trapping an Unexpected/Unprecedented Hexanuclear Ce(III) Hydrolysis Product with Neutral 4‐Amino‐1,2,4‐triazole

Wineinger,

Smetana,

Hiti

et al. 2023

Eur J Inorg Chem

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Using Ce(III) as both a representative lanthanide and actinide analog, the ability of mixtures of acidic and basic azoles to allow direct access to homoleptic N‐donor f‐element complexes in one pot reactions from hydrated salts as starting materials was examined by reacting mixtures of 4‐amino‐1,2,4‐triazole (4‐NH2‐1,2,4‐Triaz), 5‐amino‐tetrazole (5‐NH2‐HTetaz), and 1,2,3‐triazole (1,2,3‐HTriaz) in 1:1 and 1:3 ratios with CeCl3•7H2O, [C2mim]3[CeCl6] ([C2mim]+ = 2‐ethyl‐1‐methylimidazolium), and Ce(NO3)3•6H2O. Although unsuccessful in our goal, single crystal X‐ray diffraction revealed that neutral 4‐NH2‐1,2,4‐Triaz is structure directing via h2m2k2 bridging, with the formation of the dinuclear complexes [Ce2Cl2(µ2‐4‐NH2‐1,2,4‐Triaz)4(H2O)8]Cl4•4H2O, [Ce2(µ2‐4‐NH2‐1,2,4‐Triaz)4(4‐NH2‐1,2,4‐Triaz)2(Cl)6], and [4‐NH2‐1,2,4‐HTriaz][Ce2(µ2‐4‐NH2‐1,2,4‐Triaz)2(µ2‐NO3)(NO3)6(H2O)2]. When the synthetic conditions favored hydrolysis, the hexanuclear Ce(III) complex [Ce6(µ3‐O)4(µ3‐OH)2(µ3‐Cl)2(Cl)6(µ2‐4‐NH2‐1,2,4‐Triaz)12]•7H2O was isolated. This unexpected hydrolysis product represents the first example of a high nuclearity lanthanide complex where all Ln atoms are pairwise connected through 12 N‐donor ligands or 12 neutral bridging ligands of any type, a rare example of incorporation of non‐oxo coordinating anions in the M6X8 core, and the first reported Ce(III) hexanuclear complex of this type.

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Aqueous Speciation of Tetravalent Actinides in the Presence of Chloride and Nitrate Ligands

Cited by 5 publications

References 69 publications

Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO₄ Co‐Mobility in the Nuclear Fuel Cycle

Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO₄ Co‐Mobility in the Nuclear Fuel Cycle

Co-Crystallization of Plutonium(III) and Plutonium(IV) Diglycolamides with Pu(III) and Pu(IV) Hexanitrato Anions: A Route to Redox Variants of [Pu^III,IV(DGA)₃][Pu^III,IV(NO₃)₆]_x

Trapping an Unexpected/Unprecedented Hexanuclear Ce(III) Hydrolysis Product with Neutral 4‐Amino‐1,2,4‐triazole

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Aqueous Speciation of Tetravalent Actinides in the Presence of Chloride and Nitrate Ligands

Cited by 5 publications

References 69 publications

Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO4 Co‐Mobility in the Nuclear Fuel Cycle

Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO4 Co‐Mobility in the Nuclear Fuel Cycle

Co-Crystallization of Plutonium(III) and Plutonium(IV) Diglycolamides with Pu(III) and Pu(IV) Hexanitrato Anions: A Route to Redox Variants of [PuIII,IV(DGA)3][PuIII,IV(NO3)6]x

Trapping an Unexpected/Unprecedented Hexanuclear Ce(III) Hydrolysis Product with Neutral 4‐Amino‐1,2,4‐triazole

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Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO₄ Co‐Mobility in the Nuclear Fuel Cycle

Pertechnetate/perrhenate‐capped Zr/Hf‐Dihydroxide Dimers: Elucidating Zr−TcO₄ Co‐Mobility in the Nuclear Fuel Cycle

Co-Crystallization of Plutonium(III) and Plutonium(IV) Diglycolamides with Pu(III) and Pu(IV) Hexanitrato Anions: A Route to Redox Variants of [Pu^III,IV(DGA)₃][Pu^III,IV(NO₃)₆]_x