Beam-induced oxidation of monomeric U(IV) species

Alessi, D.S.; Uster, B.; Borca, C.N.; Grolimund, D.; Bernier-Latmani, R.

doi:10.1107/S0909049512041763

short communications

JOURNAL OF
SYNCHROTRON
RADIATION

ISSN: 1600-5775

Volume 20| Part 1| January 2013| Pages 197-199

https://doi.org/10.1107/S0909049512041763

Beam-induced oxidation of monomeric U(IV) species

Daniel S. Alessi,^a ^* Benjamin Uster,^a Camelia N. Borca,^b Daniel Grolimund ^b and Rizlan Bernier-Latmani ^a

^aEnvironmental Microbiology Laboratory, Ecole Polytechnique, Fédérale de Lausanne, Switzerland, and ^bSwiss Light Source, Paul Scherrer Institut, Villigen-PSI, Switzerland
^*Correspondence e-mail: daniel.alessi@epfl.ch

(Received 24 April 2012; accepted 5 October 2012; online 22 November 2012)

Uranium L_III-edge X-ray absorption spectroscopy is often used to probe the oxidation state and coordination of uranium in environmental samples, and micrometre-sized beams can be used to spatially map the distribution of uranium relative to other elements. Here a variety of uranium-containing environmental samples are analyzed at both microbeam and larger beam sizes to determine whether reoxidation of U(IV) occurred. Monomeric U(IV), a recently discovered product of U(VI) reduction by microbes and certain iron-bearing minerals at uranium-contaminated field sites, was found to be reoxidized during microbeam (3 µm × 2 µm) analysis of biomass and sediments containing the species but not at larger beam sizes. Thus, care must be taken when using X-ray microprobes to analyze samples containing monomeric U(IV).

Keywords: uranium; monomeric U(IV); X-ray absorption spectroscopy; oxidation; beam damage; microbeam.

1. Introduction

Monomeric U(IV) is a recently discovered non-crystalline product of U(VI) reduction by microbes, iron-bearing biogenic minerals and in biostimulated natural sediments (e.g. Bernier-Latmani et al., 2010 ; Fletcher et al., 2010 ; Veeramani et al., 2011 ; Sharp et al., 2011 ; Cologgi et al., 2011 ). The species may form along with the crystalline U(IV) phase uraninite, UO₂(s), in laboratory experiments and in field-scale remediation efforts that aim to reduce U(VI) to less soluble U(IV) species. Key to differentiating U(VI), uraninite and monomeric U(IV) in environmental samples is the application of U L_III-edge X-ray absorption spectroscopy (XAS) (Kelly, 2010 ). In particular, element-specific mapping using an X-ray microbeam can be employed to determine the association of heavy metals such as uranium with other elements in the sample, and provide insights into surface species and solid phases (e.g. Bertsch & Hunter, 2001 ; Kemner et al., 2004 ; Punshon et al., 2005 ). Because of the relatively high incident photon-flux density applied to the sample while using microbeam XAS techniques (Lombi et al., 2011 ), there is an increased likelihood that uraninite or monomeric U(IV) could be reoxidized during sample analysis. In this study we prepared a set of U(IV)-containing samples and a U(VI) standard and analyzed them using both a microbeam and larger beam sizes at the Swiss Light Source (SLS). The goal of our analyses was to determine what conditions, if any, would lead to U(IV) oxidation in our experimental systems.

2. Experimental

All experimental systems were prepared in duplicate, and are detailed in Table 1. A hydrous ferric oxide (HFO) was produced by precipitation of a ferric chloride solution using concentrated NaOH (see Veeramani et al., 2011). The washed HFO was suspended to 50 mM as Fe(III) in a solution containing 400 µM U(VI), and all the U(VI) was quickly adsorbed to the HFO. Uranium dioxide [U^IVO₂], hereafter referred to as chemogenic uraninite, was analyzed as received (International Bio-Analytical Industries, Boca Raton, Florida, USA). Monomeric U(IV) and biogenic uraninite were produced via U(VI) reduction by Shewanella oneidensis MR-1 bacterial cells according to the methods given by Bernier-Latmani et al. (2010). These bacterial samples were pelleted by centrifugation (10000 g for 10 min) and mounted into Teflon sample holders with Kapton^® tape windows (DuPont, Wilmington, Delaware, USA) in an anaerobic chamber containing 3% H₂(g) and a balance N₂(g). A biostimulated natural sediment from Rifle, Colorado, or RABS sediment (Anderson et al., 2003 ), containing monomeric U(IV) species (see Sharp et al., 2011) was fixed in epoxy, mounted on glass slides and polished to a thickness of 30 µm. All samples were transported to SLS in hermetically sealed stainless steel shipping canisters (Schuett-biotec GmbH, Göttingen, Germany) filled to a slightly positive pressure with N₂(g).

Table 1
Sample list

Incident fluxes are those collected using the Si photodiode detailed in §2.

Experimental system	Beam size (µm × µm)	Incident flux (amps)	Oxidation of U(IV)
Monomeric U(IV) bound to Shewanella oneidensis MR-1	3 × 2	6.30 × 10⁻⁶	Yes
	100 × 100	2.50 × 10⁻⁶	No
	500 × 500	4.20 × 10⁻⁵	No
Biogenic uraninite bound to Shewanella oneidensis MR-1	3 × 2	6.30 × 10⁻⁶	No
	100 × 100	2.60 × 10⁻⁶	No
	500 × 500	4.80 × 10⁻⁵	No
Chemogenic uraninite	3 × 2	6.30 × 10⁻⁶	No
	100 × 100	2.50 × 10⁻⁶	No
	500 × 500	4.18 × 10⁻⁵	No
RABS sediment with monomeric U(IV)	3 × 2	6.30 × 10⁻⁶	Yes
	100 × 100	2.50 × 10⁻⁶	No
	500 × 500	4.20 × 10⁻⁵	No
HFO with adsorbed U(VI)	3 × 2	6.30 × 10⁻⁶	N/A
HFO with adsorbed U(VI)	500 × 500	4.18 × 10⁻⁶	N/A

Uranium L_III-edge XAS was conducted at the microXAS beamline of the SLS. The beamline layout is described in greater detail by Borca et al. (2009 ). Using the beamline slits, samples were analyzed with a collimated `large' beam with sizes of 500 µm × 500 µm, and 100 µm × 100 µm. The X-ray microbeam was produced by condensing an initial acceptance of 300 µm × 300 µm into a spot of 3 µm × 2 µm by employing reflective mirrors. Measurements were performed in fluorescence mode and using a Si drift diode detector. A double-crystal Si(111) monochromator (DCM) was used to select energies. During analysis, samples were placed under a constant stream of N₂(g). Energies were rastered between 17.06 and 17.60 keV for 12.8 min for each scan, and 8–16 scans were collected per sample. Reduction of the XANES raw data was carried out using the ATHENA program (Ravel & Newville, 2005 ) by subtracting a background signal (fitted through an appropriate pre-edge range) and normalizing to the main edge jump. The absorption edge was defined as the energy corresponding to the first inflection point (maximum of first derivative).

An ion chamber of reduced dimensions, developed in-house, was used to monitor the incoming beam intensity (I₀) during the spectroscopic measurements, adapting the type of flowing gas with the energy needed. The photon flux of the variable beam sizes was determined using a Hamamatsu Si PIN photodiode (model S3590-02), analogous to that of Owen et al. (2009 ). The obtained photon fluxes were in close agreement with theoretical calculations based on known beamline source and optics characteristics. For the large beam sizes, the obtained flux is 2.5 × 10¹¹ monochromatic [Si(111) DCM] photons per second, while, in the microbeam, 0.4 × 10¹¹ photons per second were delivered. Assuming a photon energy of 17.2 keV, approximately 25% of incident photons were absorbed in the 200 µm-thick Si diode (Owen et al., 2009).

3. Results and discussion

The objective of the study was to determine X-ray beam conditions under which U(IV) species, including monomeric U(IV) and uraninite, may oxidize to U(VI). Of particular interest was the potential oxidation induced by X-ray microbeams because of the increased use of microbeams for elemental mapping and spatially resolved EXAFS analyses of uranium-contaminated soils and sediments. No changes in uranium valence state were observed under any beam size (500 µm × 500 µm, 100 µm × 100 µm and 3 µm × 2 µm) for the chemogenic uraninite, biogenic uraninite or HFO with adsorbed U(VI) experimental systems (Table 1). The oxidation of uranium was observed in the biomass monomeric U(IV) sample and the thin-sectioned RABS sediment. Consequently, the following discussion will focus on these experimental systems.

XANES data from the microbeam analyses of the biomass-associated monomeric U(IV) samples are presented in Fig. 1(a). A marked difference between the first scan (dotted line) and the average of seven subsequent scans (solid line) is observed. In particular, there is a shift in the position and intensity of the white line, and a flattening and rise in the region centred around 17.19 keV, marked with arrows. The feature at 17.19 keV is typically associated with U(VI), probably the more tightly bound axial O atoms of the uranyl [U^VIO₂²⁺] cation (Kelly, 2010) as is observed for the U(VI) standard. Therefore, the shift observed between the first and subsequent scans is indicative of uranium oxidation. The averaged spectra for the HFO + U(VI) system (dashed line) show the presence of these features in a sample that contains 100% U(VI). Fig. 1(b) displays XANES spectra collected under large beam (500 µm × 500 µm) conditions. Essentially no change is observed between the initial scan (dotted line) and the average of subsequent scans (solid line) of the biomass monomeric U(IV) sample. Hence, the observed beam damage is attributable to the microbeam conditions (3 µm × 2 µm) rather than the sample run conditions.

Figure 1
Uranium L_III-edge XANES data of monomeric U(VI) containing biomass, collected under (a) microbeam (3 µm × 2 µm) and (b) large beam (500 µm × 500 µm) conditions at the microXAS beamline. A significant change is observed between the first scan (dotted line) and subsequent scans (solid line) of the biomass monomeric U(IV) system under microbeam conditions, likely due to U(IV) oxidation by the microbeam. The subsequent scans show a slight shift in white-line energy and a flattening in the post-edge region centred around 17.19 keV, changes indicated with arrows in the figure. These features are present in the HFO + U(VI) system (dashed line), which is included for reference. The changes are not seen under large beam (500 µm × 500 µm) conditions where the initial scan (dotted line) is occluded by the later scans (solid line) due to perfect overlap (b).

Fig. 2 displays the XANES results from the biostimulated RABS sediment containing monomeric U(IV). Similar to the biomass monomeric U(IV) system, there is a large change between the first XAS spectrum (dotted line) and the average of seven subsequent scans (solid line) during microbeam analyses (Fig. 2a). The same shift in the white line and resonance feature at 17.19 keV is also observed, indicative of monomeric U(IV) oxidation in the slide-mounted sediment sample. No change is observed between the first scan (dotted line) and subsequent scans (solid line) when the same sample is analyzed using the 500 µm × 500 µm beam size (Fig. 2b).

Figure 2
Uranium L_III-edge XANES data of sediment from Rifle, Colorado, containing primarily monomeric U(IV) species (see Sharp et al., 2011

), collected using (a) the X-ray microbeam and (b) the large beam (500 µm × 500 µm). Oxidation of monomeric U(IV) by the microbeam between the first scan (dotted line) and the average of seven subsequent scans (solid line) is shown by the shift in the white line and particularly the flattening in the post-edge region centred around 17.19 keV (a). A uranyl acetate U(VI) standard is included for reference (dashed line). There is little change in spectral shape observed between the first scan (dotted line) and the average of nine subsequent scans (solid line) under the large beam (b).

The flux density (photons per µm²) is more than 6000 times greater under microbeam conditions than the large beam (500 µm × 500 µm) in the two monomeric U(IV) systems. Because of the much smaller spot size used in microprobe analyses, a higher incident flux density is necessary for the collection of XAS data of sufficient quality. The relatively intense beam can lead to dehydration (heating) of hydrated organic samples (e.g. Lombi et al., 2011), and in our study likely lead to the oxidation of redox-sensitive monomeric U(IV) species to U(VI) after approximately 13 min of beam exposure.

4. Conclusions

XAS analyses of U(VI), uraninite and monomeric U(IV) containing systems indicate that monomeric U(IV) may be oxidized in biomass and sediment samples under X-ray microbeam conditions. Specifically, we show that the microbeam alters the XANES spectra of biomass-associated monomeric U(IV) and monomeric U(IV) contained in natural sediments, consistent with oxidation to U(VI). Those employing X-ray microbeams to perform element-mapping or micrometre-scale EXAFS analyses of samples that may contain monomeric U(IV) should consider that the species may be oxidized owing to the intensity of incoming photons.

Acknowledgements

The authors thank Kelly Plathe for her assistance in XAS analyses of the samples. DSA was partially supported by a Marie Curie International Incoming Fellowship from the European Commission, grant FP7-PEOPLE-2009-IIF-254143. This work was performed at the microXAS beamline (proposal 20091011) of the Swiss Light Source, Paul Scherrer Institut, Villigen, Switzerland.

References

Anderson, R. T., Vrionis, H. A., Ortiz-Bernad, I., Resch, C. T., Long, P. E., Dayvault, R., Karp, K., Marutzky, S., Metzler, D. R., Peacock, A., White, D. C., Lowe, M. & Lovley, D. R. (2003). Appl. Environ. Microbiol. 69, 5884–5891. Web of Science CrossRef PubMed CAS Google Scholar
Bernier-Latmani, R., Veeramani, H., Vecchia, E. D., Junier, P., Lezama-Pacheco, J. S., Suvorova, E. I., Sharp, J. O., Wigginton, N. S. & Bargar, J. R. (2010). Environ. Sci. Technol. 44, 9456–9462. Web of Science CAS PubMed Google Scholar
Bertsch, P. M. & Hunter, D. B. (2001). Chem. Rev. 101, 1809–1842. Web of Science CrossRef PubMed CAS Google Scholar
Borca, C. N., Grolimund, D., Willimann, M., Meyer, B., Jefimovs, K., Vila-Comamala, J. & David, C. (2009). J. Phys. Conf. Ser. 186, 012003. CrossRef Google Scholar
Cologgi, D. L., Lampa-Pastirk, S., Speers, A. M., Kelly, S. D. & Reguera, G. (2011). Proc. Natl. Acad. Sci. USA, 37, 15248–15252. Web of Science CrossRef Google Scholar
Fletcher, K. E., Boyanov, M. I., Thomas, S. H., Wu, Q., Kemner, K. M. & Löffler, F. E. (2010). Environ. Sci. Technol. 44, 4705–4709. Web of Science CrossRef CAS PubMed Google Scholar
Kelly, S. D. (2010). Synchrotron-Based Techniques in Soils and Sediments, Vol. 34, edited by B. Singh and M. Gräfe, 1st ed, pp. 411–466. Oxford: Elsevier. Google Scholar
Kemner, K. M., Kelly, S. D., Lai, B., Maser, J., O'Loughlin, E. J., Sholto-Douglas, D., Cai, Z., Schneegurt, M. A., Kulpa, C. F. & Nealson, K. H. (2004). Science, 306, 686–687. Web of Science CrossRef PubMed CAS Google Scholar
Lombi, E., de Jonge, M. D., Donner, E., Ryan, C. G. & Paterson, D. (2011). Anal. Bioanal. Chem. 400, 1637–1644. Web of Science CrossRef CAS PubMed Google Scholar
Owen, R. L., Holton, J. M., Schulze-Briese, C. & Garman, E. F. (2009). J. Synchrotron Rad. 16, 143–151. Web of Science CrossRef CAS IUCr Journals Google Scholar
Punshon, T., Jackson, B. P., Lanzirotti, A., Hopkins, W. A., Bertsch, P. M. & Burger, J. (2005). Spectrosc. Lett. 38, 343–363. Web of Science CrossRef CAS Google Scholar
Ravel, B. & Newville, M. (2005). J. Synchrotron Rad. 12, 537–541. Web of Science CrossRef CAS IUCr Journals Google Scholar
Sharp, J. O., Lezama-Pacheco, J. S., Schofield, E. J., Junier, P., Ulrich, K.-U., Chinni, S., Veeramani, H., Margot-Roquier, C., Webb, S. M., Tebo, B. M., Giammar, D., Bargar, J. R. & Bernier-Latmani, R. (2011). Geochim. Cosmochim. Acta, 75, 6497–6510. Web of Science CrossRef CAS Google Scholar
Veeramani, H., Alessi, D. S., Suvorova, E. I., Lezama-Pacheco, J. S., Stubbs, J. E., Sharp, J. O., Dippon, U., Kappler, A., Bargar, J. R. & Bernier-Latmani, R. (2011). Geochim. Cosmochim. Acta, 75, 2512–2528. Web of Science CrossRef CAS Google Scholar

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