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3. Photon-Modulated Bond Covalency of [Sm(II)(η9-C9H9)2]

Author

Vitova, T., Ramanantoanina, H., Schacherl, B., Münzfeld, L., Hauser, A., Ekanayake, R. S. K., Reitz, C. Y., Prüßmann, T., Neill, T. S., Göttlicher, J., Steininger, R., Saveleva, V. A., Haverkort, M. W., and Roesky, P. W.

Abstract

Lanthanides are widely assumed not to form covalent bonds due to the localized nature of their 4f valence electrons. This work demonstrates that the ionic bond of Sm(II) with cyclononatetraenyl (η9-C9H9–) in [Sm(η9-C9H9)2] can be modulated and becomes more covalent by photon-induced transfer of Sm 4f electrons to Sm 5d orbitals. This photon-induced change in bonding properties facilitates a subsequent reconfiguration of [Sm(η9-C9H9)2]. As a result, Sm–C bond length contraction is detected and the local Sm coordination environment exhibits more extensive disorder. Both Sm 4f and 5d electrons have increased participation in covalent Sm–ligand interactions. The Sm L3-edge valence band resonant inelastic X-ray scattering (VB-RIXS), high-resolution X-ray absorption near-edge structure (HR-XANES), and quantum chemical computations showcase a spectroscopic methodology for in-depth studies of bond covalency of lanthanide atoms.

Published
2024
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4. Insight into the structure-property relationship of UO2 nanoparticles

Author

Gerber, E., Romanchuk, A. Y., Weiss, S., Bauters, S., Schacherl, B., Vitova, T., (0000-0002-5200-6928) Hübner, R., Shams Aldin Azzam, S., Detollenaere, D., Banerjee, D., Butorin, S. M., Kalmykov, S. N., (0000-0003-4447-4542) Kvashnina, K., Gerber, E., Romanchuk, A. Y., Weiss, S., Bauters, S., Schacherl, B., Vitova, T., (0000-0002-5200-6928) Hübner, R., Shams Aldin Azzam, S., Detollenaere, D., Banerjee, D., Butorin, S. M., Kalmykov, S. N., and (0000-0003-4447-4542) Kvashnina, K.

Abstract

Fast chemical deposition of uranium(IV) under reducing conditions at pH 8-11 results in the formation of highly crystalline UO2 nanoparticles (NPs) with sizes of 2-3 nm, which is similar to the formation mechanism of PuO2 NPs. UO2 NPs are characterized by various microscopic and spectroscopic techniques including high energy transmission electron microscopy (HRTEM), high energy resolution fluorescence detection (HERFD) X-ray absorption spectroscopy and extended X-ray absorption fine structure (EXAFS) spectroscopy. Despite U(IV) being the dominant oxidation state of the freshly prepared UO2 NPs, they readily oxidize to U4O9 with time and under the X-ray beam. This oxidation of NPs is accompanied by their growth in size to 6 nm. The high tendency of UO2 NPs towards oxidation differs from PuO2 NPs’ behaviour due to the extremely high stability of Pu(IV) and much lower stability of oxidized Pu(V/VI) as compared to U(V/VI).

Published
2021

7. Resonant inelastic X-ray scattering tools to count 5 f electrons of actinides and probe bond covalency.

Author

Schacherl B, Tagliavini M, Kaufmann-Heimeshoff H, Göttlicher J, Mazzanti M, Popa K, Walter O, Pruessmann T, Vollmer C, Beck A, Ekanayake RSK, Branson JA, Neill T, Fellhauer D, Reitz C, Schild D, Brager D, Cahill C, Windorff C, Sittel T, Ramanantoanina H, Haverkort MW, and Vitova T

Abstract

The actinides possess a complex electronic structure, making their chemical and physical properties among the least understood in the periodic table. Advanced spectroscopic tools, able to obtain deep insights into the electronic structure and binding properties of the actinides, are highly desirable. Here, we introduce two sensitive spectroscopic tools: one determines the number of localized 5f electrons on an actinide atom, and another assesses the covalent character of actinide-ligand bonding. Both tools are based on the multiplet structure present in actinide M 4 edge core-to-core resonant inelastic X-ray scattering (CC-RIXS) maps. The spectral intensity of different many-body final-state multiplets directly depends on the local many-electron ground-state symmetry including the local 5 f spin configuration. By comparing U M 4 edge CC-RIXS data for 21 U, Np, Pu and Am compounds, we demonstrate the ability to compare the number of localized 5 f electrons and bond covalency across the actinide series., Competing Interests: Competing interests: The authors declare no competing interests., (© 2025. The Author(s).)

Published
2025
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8. A fully contained sample holder capable of electron-yield detection at soft X-ray energies.

Author

Gunther SO, Smith PW, Branson JA, Ditter AS, Minasian SG, N'Diaye AT, Schacherl B, and Shuh DK

Abstract

A holder has been developed that enables electron yield-detected soft X-ray spectroscopy of fully contained samples at low temperature. Crucially, this design uses elements of the sample containment to collect ejected electrons, removing the need to expose samples directly to the vacuum environment of the spectrometer. The design is modular and should be adaptable to a number of different endstation configurations, enabling spectroscopy of air-sensitive, radioactive and vacuum-sensitive (biological) samples., (open access.)

Published
2025
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9. Bonding and Interactions in UO 2 2+ for Ground and Core Excited States: Extracting Chemistry from Molecular Orbital Calculations.

Author

Bagus PS, Nelin CJ, Schacherl B, Vitova T, and Polly R

Abstract

Theoretical analyses of actinyls are necessary in order to understand and correctly interpret the chemical and physical properties of these molecules. Here, wave functions of Uranyl, UO 2 2+ , are considered for the ground state and for the core excited states where an electron is promoted from the U 3d 5/2 shell into a low-lying unoccupied orbital that is U 5f antibonding with the ligand, O, orbitals. A focus is on the application of novel theoretical methods to the analysis of these wave functions so that measurements, especially with X-ray absorption, can be related to the UO 2 2+ chemical bonding. The bond covalency is examined with these theoretical methods. The study includes how the covalent character is different for the ground and excited configurations and how this character changes as the U-O distance is changed. Furthermore, analyses are mode of how many-body effects may modify excitation energies and X-ray adsorption intensities. This includes determining the extent to which a single configuration provides a satisfactory model for the UO 2 2+ wave functions. Two distinct types of many-body effects are considered. One involves the angular momentum coupling of the open shell electrons in the excited states to yield correct multiplets. The second adds excitations from shells that are bonding into the antibonding open shell space. These excitations are essential to properly describe the X-ray adsorption. While these many-body effects must be taken into account, their importance and their role can be explained and understood using orbitals and orbital occupations.

Published
2024
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10. Photon-Modulated Bond Covalency of [Sm(II)(η 9 -C 9 H 9 ) 2 ].

Author

Vitova T, Ramanantoanina H, Schacherl B, Münzfeld L, Hauser A, Ekanayake RSK, Reitz CY, Prüßmann T, Neill TS, Göttlicher J, Steininger R, Saveleva VA, Haverkort MW, and Roesky PW

Abstract

Lanthanides are widely assumed not to form covalent bonds due to the localized nature of their 4f valence electrons. This work demonstrates that the ionic bond of Sm(II) with cyclononatetraenyl (η 9 -C 9 H 9 - ) in [Sm(η 9 -C 9 H 9 ) 2 ] can be modulated and becomes more covalent by photon-induced transfer of Sm 4f electrons to Sm 5d orbitals. This photon-induced change in bonding properties facilitates a subsequent reconfiguration of [Sm(η 9 -C 9 H 9 ) 2 ]. As a result, Sm-C bond length contraction is detected and the local Sm coordination environment exhibits more extensive disorder. Both Sm 4f and 5d electrons have increased participation in covalent Sm-ligand interactions. The Sm L 3 -edge valence band resonant inelastic X-ray scattering (VB-RIXS), high-resolution X-ray absorption near-edge structure (HR-XANES), and quantum chemical computations showcase a spectroscopic methodology for in-depth studies of bond covalency of lanthanide atoms.

Published
2024
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11. Actinyl Electronic Structure Probed by XAS: The Role of Many-Body Effects.

Author

Bagus PS, Nelin CJ, Schacherl B, and Vitova T

Abstract

A detailed analysis of the wave functions for the M 5 to 5f excitations in the linear actinyls, UO 2 2+ , NpO 2 2+ , and PuO 2 2+ , and the theoretical X-ray absorption spectra obtained with these wave functions in comparison with experimental M 5 -edge high-resolution X-ray absorption near-edge structure (HR-XANES) spectra is presented. The wave functions include full treatment of scalar and spin-orbit relativistic effects through the use of a Dirac-Coulomb Hamiltonian; many-body effects are included in determining the wave functions. The character of the excited states and of the active spaces to describe the wave functions for these states are investigated and analyzed. It is shown that the excited states cannot, in general, be described with a single configuration but have an essential multiconfiguration character. The characterization of the properties of the excited states and the X-ray absorption spectra was achieved through the use of novel methods.

Published
2024
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13. Electronic Structure of Actinyls: Orbital Properties.

Author

Bagus PS, Nelin CJ, Rosso KM, Schacherl B, and Vitova T

Abstract

A detailed analysis is presented for the covalent character of the orbitals in the actinyls: UO 2 2+ , NpO 2 2+ , and PuO 2 2+ . Both the initial, or ground state, GS, configuration and the excited configurations where a 3d electron is excited into the open valence, nominally the 5f shell, are considered. The orbitals are determined as fully relativistic, four component Dirac-Coulomb Hartree-Fock solutions. Several measures, which go beyond the commonly used population analyses, are used to characterize the covalent character of an orbital in order to obtain reliable estimates of the covalency. Although there are differences in the covalent character of the orbitals for the initial and excited configurations of the different actinyls, there is a surprising similarity in the covalent character for all of the states considered. This is true both between the initial and excited configurations as well as between the different actinyls. The analysis emphasizes the 5f covalent character in the closed shell bonding orbitals and the open shell antibonding orbitals since the focus is on characterizing orbitals needed in a many-body treatment of the actinyl wave functions. However, estimates are also made of the participation of the actinide 6d in the covalent bonding.

Published
2024
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14. Np(V) Retention at the Illite du Puy Surface.

Author

Schacherl B, Joseph C, Beck A, Lavrova P, Schnurr A, Dardenne K, Geyer F, Cherkezova-Zheleva Z, Göttlicher J, Geckeis H, and Vitova T

Subjects
Bentonite chemistry, Ferrous Compounds chemistry, Ferric Compounds, Minerals chemistry
Abstract

In this study, Np(V) retention on Illite du Puy (IdP) was investigated since it is essential for understanding the migration behavior of Np in argillaceous environments. The presence of structural Fe(III) and Fe(II) in IdP was confirmed by Fe K-edge X-ray absorption near-edge structure (XANES) and 57 Fe Mössbauer spectroscopy. In batch sorption experiments, a higher Np sorption affinity to IdP was found than to Wyoming smectite or iron-free synthetic montmorillonite. An increase of the relative Np(IV) ratio sorbed onto IdP with decreasing pH was observed by solvent extraction (up to (24 ± 2)% at pH 5, c 0 (Np) = 10 -6 mol/L). Furthermore, up to (33 ± 5)% Np(IV) could be detected in IdP diffusion samples at pH 5. Respective Np M 5 -edge high-energy resolution (HR-) XANES spectra suggested the presence of Np(IV/V) mixtures and weakened axial bond covalency of the NpO 2 + species sorbed onto IdP. Np L 3 -edge extended X-ray absorption fine structure (EXAFS) analysis showed that significant fractions of Np were coordinated to Fe─O entities at pH 9. This highlights the potential role of Fe(II/III) clay edge sites as a strong Np(V) surface complex partner and points to the partial reduction of sorbed Np(V) to Np(IV) via structural Fe(II).

Published
2023
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15. The mechanism of Fe induced bond stability of uranyl(v).

Author

Vitova T, Faizova R, Amaro-Estrada JI, Maron L, Pruessmann T, Neill T, Beck A, Schacherl B, Tirani FF, and Mazzanti M

Abstract

The stabilization of uranyl(v) (UO 2 1 + ) by Fe(ii) in natural systems remains an open question in uranium chemistry. Stabilization of U V O 2 1+ by Fe(ii) against disproportionation was also demonstrated in molecular complexes. However, the relation between the Fe(ii) induced stability and the change of the bonding properties have not been elucidated up to date. We demonstrate that U(v) - oaxial bond covalency decreases upon binding to Fe(ii) inducing redirection of electron density from the U(v) - oaxial bond towards the U(v) - equatorial bonds thereby increasing bond covalency. Our results indicate that such increased covalent interaction of U(v) with the equatorial ligands resulting from iron binding lead to higher stability of uranyl(v). For the first time a combination of U M 4,5 high energy resolution X-ray absorption near edge structure (HR-XANES) and valence band resonant inelastic X-ray scattering (VB-RIXS) and ab initio multireference CASSCF and DFT based computations were applied to establish the electronic structure of iron-bound uranyl(v)., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published
2022
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16. Paving the way for examination of coupled redox/solid-liquid interface reactions: 1 ppm Np adsorbed on clay studied by Np M 5 -edge HR-XANES spectroscopy.

Author

Schacherl B, Joseph C, Lavrova P, Beck A, Reitz C, Pruessmann T, Fellhauer D, Lee JY, Dardenne K, Rothe J, Geckeis H, and Vitova T

Subjects
Clay, Oxidation-Reduction, Temperature, X-Rays, X-Ray Absorption Spectroscopy methods
Abstract

The recently emerged actinide (An) M 4,5 -edge high-energy resolution X-ray absorption near-edge structure (HR-XANES) technique has proven to be very powerful for oxidation state studies of actinides. In this work, for the first time, Np M 5 -edge HR-XANES was applied to study Np sorption on illite. By improving the experimental conditions, notably by operation of the spectrometer under He atmosphere, it was possible to measure Np M 5 -edge HR-XANES spectra of a sample with ≈ 1 μg Np/g illite (1 ppm). This is 30-2000 times lower than Np loadings on mineral surfaces usually investigated by X-ray absorption spectroscopy. A newly designed cryogenic configuration enabled sample temperatures of 141.2 ± 1.5 K and successfully prevented beam-induced changes of the Np oxidation state. The described approach paves the way for the examination of coupled redox/solid-liquid interface reactions of actinide ions via An M 4,5 -edge HR-XANES spectroscopy at low metal ion concentrations, which are of specific relevance for contaminated sites and nuclear waste disposal studies., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 The Authors. Published by Elsevier B.V. All rights reserved.)

Published
2022
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17. Implementation of cryogenic tender X-ray HR-XANES spectroscopy at the ACT station of the CAT-ACT beamline at the KIT Light Source.

Author

Schacherl B, Prüssmann T, Dardenne K, Hardock K, Krepper V, Rothe J, Vitova T, and Geckeis H

Abstract

The ACT experimental station of the CAT-ACT wiggler beamline at the Karlsruhe Institute of Technology (KIT) Light Source is dedicated to the investigation of radionuclide materials with radioactivities up to 1000000 times the exemption limit by various speciation techniques applying monochromatic X-rays. In this article, the latest technological developments at the ACT station that enable high-resolution X-ray absorption near-edge structure (HR-XANES) spectroscopy for low radionuclide loading samples are highlighted - encompassing the investigation of actinide elements down to 1 p.p.m. concentration - combined with a cryogenic sample environment reducing beam-induced sample alterations. One important part of this development is a versatile gas tight plexiglass encasement ensuring that all beam paths in the five-analyzer-crystal Johann-type X-ray emission spectrometer run within He atmosphere. The setup enables the easy exchange between different experiments (conventional X-ray absorption fine structure, HR-XANES, high-energy or wide-angle X-ray scattering, tender to hard X-ray spectroscopy) and opens up the possibility for the investigation of environmental samples, such as specimens containing transuranium elements from contaminated land sites or samples from sorption and diffusion experiments to mimic the far field of a breached nuclear waste repository., (open access.)

Published
2022
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18. Fe(II) Induced Reduction of Incorporated U(VI) to U(V) in Goethite.

Author

Stagg O, Morris K, Lam A, Navrotsky A, Velázquez JM, Schacherl B, Vitova T, Rothe J, Galanzew J, Neumann A, Lythgoe P, Abrahamsen-Mills L, and Shaw S

Subjects
Ferrous Compounds, Minerals, Oxidation-Reduction, Ferric Compounds, Iron Compounds
Abstract

Over 60 years of nuclear activities have resulted in a global legacy of radioactive wastes, with uranium considered a key radionuclide in both disposal and contaminated land scenarios. With the understanding that U has been incorporated into a range of iron (oxyhydr)oxides, these minerals may be considered a secondary barrier to the migration of radionuclides in the environment. However, the long-term stability of U-incorporated iron (oxyhydr)oxides is largely unknown, with the end-fate of incorporated species potentially impacted by biogeochemical processes. In particular, studies show that significant electron transfer may occur between stable iron (oxyhydr)oxides such as goethite and adsorbed Fe(II). These interactions can also induce varying degrees of iron (oxyhydr)oxide recrystallization (<4% to >90%). Here, the fate of U(VI)-incorporated goethite during exposure to Fe(II) was investigated using geochemical analysis and X-ray absorption spectroscopy (XAS). Analysis of XAS spectra revealed that incorporated U(VI) was reduced to U(V) as the reaction with Fe(II) progressed, with minimal recrystallization (approximately 2%) of the goethite phase. These results therefore indicate that U may remain incorporated within goethite as U(V) even under iron-reducing conditions. This develops the concept of iron (oxyhydr)oxides acting as a secondary barrier to radionuclide migration in the environment.

Published
2021
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19. Relativistic Multiconfigurational Ab Initio Calculation of Uranyl 3d4f Resonant Inelastic X-ray Scattering.

Author

Polly R, Schacherl B, Rothe J, and Vitova T

Abstract

We applied relativistic multiconfigurational all-electron ab initio calculations including the spin-orbit interaction to calculate the 3d4f resonant inelastic X-ray scattering (RIXS) map (3d 3/2 → 5f 5/2 U M 4 absorption edge and 4f 5/2 → 3d 3/2 U M β emission) of uranyl (UO 2 2+ ). The calculated data are in excellent agreement with experimental results and allow a detailed understanding of the observed features and an unambiguous assignment of all involved intermediate and final states. The energies corresponding to the maxima of the resonant emission and the non-resonant (normal) emission were determined with high accuracy, and the corresponding X-ray absorption near edge structure spectra extracted at these two positions were simulated and agree well with the measured data. With the high quality of our theoretical data, we show that the cause of the splitting of the three main peaks in emission is due to the fine structure splitting of the 4f orbitals induced through the trans di-oxo bonds in uranyl and that we are able to obtain direct information about the energy differences between the 5f and 4f orbitals: Δ5f δ/ϕ - 4f δ/ϕ, Δ5f π* - 4f π, and Δ5f σ* - 4f σ from the 3d4f RIXS map. RIXS maps contain a wealth of information, and ab initio calculations facilitate an understanding of their complex structure in a clear and transparent way. With these calculations, we show that the multiconfigurational protocol, which is nowadays applied as a standard tool to study the X-ray spectra of transition metal complexes, can be extended to the calculation of RIXS maps of systems containing actinides.

Published
2021
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20. Computational and Spectroscopic Tools for the Detection of Bond Covalency in Pu(IV) Materials.

Author

Bagus PS, Schacherl B, and Vitova T

Abstract

Plutonium is used as a major component of new-generation nuclear fuels and of radioisotope batteries for Mars rovers, but it is also an environmental pollutant. Plutonium clearly has high technological and environmental importance, but it has an extremely complex, not well-understood electronic structure. The level of covalency of the Pu 5f valence orbitals and their role in chemical bonding are still an enigma and thus at the frontier of research in actinide science. We performed fully relativistic quantum chemical computations of the electronic structure of the Pu 4+ ion and the PuO 2 compound. Using four different theoretical tools, it is shown that the 5f orbitals have very little covalent character although the 5f( 7/2 ) a 2u orbital with the highest orbital energy has the greatest extent of covalency in PuO 2 . It is illustrated that the Pu M 4,5 edge high-energy resolution X-ray absorption near-edge structure (Pu M 4,5 HR-XANES) spectra cannot be interpreted in terms of dipole selection rules applied between individual 3d and 5f orbitals, but the selection rules must be applied between the total wavefunctions for the initial and excited states. This is because the states cannot be represented by single determinants. They are shown to involve major redistributions on the 5f electrons over the different 5f orbitals. These redistributions could be viewed as shake-up-like excitations in the 5f shell from the lowest orbital energy from J = 5f( 5/2 ) into higher orbital energy J = 5f( 7/2 ). We show that the second peak in the Pu M 4 edge and the high-energy shoulder of the Pu M 5 edge HR-XANES spectra probe the 5f( 7/2 ) a 2u orbital; thus, these spectral features are expected to change upon bond variations. We describe theoretical and spectroscopy tools, which can be applied for all actinide elements in materials with cubic structure.

Published
2021
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21. Radiochemical Determination of Long-Lived Radionuclides in Proton-Irradiated Heavy Metal Targets: Part II Tungsten.

Author

Talip Z, Dressler R, Schacherl B, David JC, Vockenhuber C, and Schumann D

Subjects
Radiochemistry, Radioisotopes, Tantalum, Protons, Tungsten
Abstract

In this study, proton-irradiated tungsten targets, up to 2.6 GeV, were investigated for the purpose of the experimental cross-section measurements. Radiochemical separation methods were applied to isolate the residual long-lived alpha-emitters 148 Gd, 154 Dy, and 146 Sm and the beta-emitters 129 I and 36 Cl from proton-irradiated tungsten targets. The molecular plating technique has been applied to prepare 148 Gd, 154 Dy, and 146 Sm samples for alpha-spectrometry. Production cross-sections of 129 I and 36 Cl were determined by means of accelerator mass spectrometry. The results are compared with theoretical predictions, obtained with the INCL++-ABLA07 codes, showing good agreement for 36 Cl and 148 Gd, while a factor of 4 difference was observed for 154 Dy, similar to the results obtained for tantalum targets.

Published
2021
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22. Sulfidation of magnetite with incorporated uranium.

Author

Townsend LT, Morris K, Harrison R, Schacherl B, Vitova T, Kovarik L, Pearce CI, Mosselmans JFW, and Shaw S

Subjects
Ferrosoferric Oxide, Iron, Oxidation-Reduction, Radioactive Waste, Uranium
Abstract

Uranium (U) is a radionuclide of key environmental interest due its abundance by mass within radioactive waste and presence in contaminated land scenarios. Ubiquitously present iron (oxyhydr)oxide mineral phases, such as (nano)magnetite, have been identified as candidates for immobilisation of U via incorporation into the mineral structure. Studies of how biogeochemical processes, such as sulfidation from the presence of sulfate-reducing bacteria, may affect iron (oxyhydr)oxides and impact radionuclide mobility are important in order to underpin geological disposal of radioactive waste and manage radioactively contaminated land. Here, this study utilised a highly controlled abiotic method for sulfidation of U(V) incorporated into nanomagnetite to determine the fate and speciation of U. Upon sulfidation, transient release of U into solution occurred (∼8.6% total U) for up to 3 days, despite the highly reducing conditions. As the system evolved, lepidocrocite was observed to form over a period of days to weeks. After 10 months, XAS and geochemical data showed all U was partitioned to the solid phase, as both nanoparticulate uraninite (U(IV)O 2 ) and a percentage of retained U(V). Further EXAFS analysis showed incorporation of the residual U(V) fraction into an iron (oxyhydr)oxide mineral phase, likely nanomagnetite or lepidocrocite. Overall, these results provide new insights into the stability of U(V) incorporated iron (oxyhydr)oxides during sulfidation, confirming the longer term retention of U in the solid phase under complex, environmentally relevant conditions., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published
2021
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23. Biological Reduction of a U(V)-Organic Ligand Complex.

Author

Molinas M, Faizova R, Brown A, Galanzew J, Schacherl B, Bartova B, Meibom KL, Vitova T, Mazzanti M, and Bernier-Latmani R

Subjects
Biodegradation, Environmental, Ligands, Oxidation-Reduction, Shewanella, Uranium
Abstract

Metal-reducing microorganisms such as Shewanella oneidensis MR-1 reduce highly soluble species of hexavalent uranyl (U(VI)) to less mobile tetravalent uranium (U(IV)) compounds. The biologically mediated immobilization of U(VI) is being considered for the remediation of U contamination. However, the mechanistic underpinnings of biological U(VI) reduction remain unresolved. It has become clear that a first electron transfer occurs to form pentavalent (U(V)) intermediates, but it has not been definitively established whether a second one-electron transfer can occur or if disproportionation of U(V) is required. Here, we utilize the unusual properties of dpaea 2- ((dpaeaH 2 ═bis(pyridyl-6-methyl-2-carboxylate)-ethylamine)), a ligand forming a stable soluble aqueous complex with U(V), and investigate the reduction of U(VI)-dpaea and U(V)-dpaea by S. oneidensis MR-1. We establish U speciation through time by separating U(VI) from U(IV) by ion exchange chromatography and characterize the reaction end-products using U M 4 -edge high resolution X-ray absorption near-edge structure (HR-XANES) spectroscopy. We document the reduction of solid phase U(VI)-dpaea to aqueous U(V)-dpaea but, most importantly, demonstrate that of U(V)-dpaea to U(IV). This work establishes the potential for biological reduction of U(V) bound to a stabilizing ligand. Thus, further work is warranted to investigate the possible persistence of U(V)-organic complexes followed by their bioreduction in environmental systems.

Published
2021
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