Hostname: page-component-78c5997874-8bhkd Total loading time: 0 Render date: 2024-11-06T09:51:31.478Z Has data issue: false hasContentIssue false

Eu(III) coprecipitation with the trioctahedral clay mineral, hectorite

Published online by Cambridge University Press:  01 January 2024

Heike Pieper*
Affiliation:
Forschungszentrum Karlsruhe, Institut für Nukleare Entsorgung (INE), PO Box 3640, 76021 Karlsruhe, Germany
Dirk Bosbach
Affiliation:
Forschungszentrum Karlsruhe, Institut für Nukleare Entsorgung (INE), PO Box 3640, 76021 Karlsruhe, Germany
Petra J. Panak
Affiliation:
Forschungszentrum Karlsruhe, Institut für Nukleare Entsorgung (INE), PO Box 3640, 76021 Karlsruhe, Germany
Thomas Rabung
Affiliation:
Forschungszentrum Karlsruhe, Institut für Nukleare Entsorgung (INE), PO Box 3640, 76021 Karlsruhe, Germany
Thomas Fanghänel
Affiliation:
Forschungszentrum Karlsruhe, Institut für Nukleare Entsorgung (INE), PO Box 3640, 76021 Karlsruhe, Germany
*
*E-mail address of corresponding author: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Various secondary phases formed during alteration/dissolution of HLW (high-level nuclear waste) borosilicate glass represent a significant retention potential for radionuclides including divalent actinides. The trioctahedral smectite, hectorite, Na0.7[Li0.7Mg5.3Si8O20(OH)4], is one of the secondary phases identified within the alteration layer of corroded HLW glass. Numerous studies have clearly shown that many radionuclides are associated with clay minerals and the migration of radionuclides is strongly reduced by complexation. Due to the structural complexity and chemical variability of smectites, sorption of radionuclides involves several sorption mechanisms: (1) adsorption via inner-sphere and outer-sphere complexation; (2) cation exchange in the interlayer; and (3) incorporation into the smectite structure. Up to now, it was not known whether trivalent actinides such as Cm(III) and Am(III) become incorporated into the crystal structure of clay minerals like hectorite. We have used a new method, developed by Carrado et al. (1997b), to synthesize a Eu- and a Cm-containing hectorite, utilizing Cm(III) and chemically homologous Eu(III) coprecipitated with Mg(OH)2 as a precursor. X-ray diffraction, Fourier transform infrared spectroscopy and atomic force microscopy identified the reaction products unambiguously as hectorite. The sorption mechanisms of Eu associated with the synthesized hectorite were investigated by time-resolved laser fluorescence spectroscopy (TRLFS). An unhydrated Eu species (fluorescence lifetime 930 µs) and a partly hydrated Eu species (fluorescence lifetime 381 µs) could be identified. The unhydrated Eu species can be interpreted as incorporating Eu(III) into the hectorite structure or a remaining X-ray amorphous silica phase. The spectra of Eu hectorite and the Eu silica complexation are too similar to permit differentiation between these species, but dialysis experiments demonstrated the close association of the unhydrated Eu species with the crystalline hectorite phase. Time-resolved laser fluorescence spectroscopy (TRLFS) measurements identified the same incorporated Eu species as long as the Eu hectorite was stable under acidic conditions. The stability of the Eu hectorite could be shown by the dialysis experiment over a time period of 160 h. Between 160 und 500 h, hectorite became unstable and a new silica phase was detected. In addition, TRLFS measurements of the Cm-containing hectorite confirmed the incorporation of actinides in the smectite structure. The Cm-hectorite and Cm-silica species can be differentiated unambiguously by TRLFS. In order to differentiate between coprecipitated and surface-sorbed Eu species, batch sorption studies were performed with synthetic Eu-free hectorite. For the surface-sorbed Eu species, a fluorescence lifetime of 284 µs (3.1 H2O molecules) was found, which clearly differs from the coprecipitated species with a fluorescence lifetime of 930 µs. The different lifetimes indicate a different chemical environment. Based on all observations it seems to be very likely that trace amounts of Cm/Eu occupy a distorted octahedral site in the hectorite.

Type
Research Article
Copyright
Copyright © 2006, The Clay Minerals Society

References

Abdelouas, A. Crovisier, J.L. Lutze, W. Muller, R. and Bernotat, W., (1995) Structure and chemical properties of surface layers developed on R7t7 simulated nuclear waste glass altered in brine at 190°C European Journal of Mineralogy 7 11011113 10.1127/ejm/7/5/1101.CrossRefGoogle Scholar
Abdelouas, A. Crovisier, J.L. Lutze, W. Grambow, B. Dran, J.C. and Müller, R., (1997) Surface layers on a borosilicate nuclear waste glass corroded in MgCl2 solution Journal of Nuclear Materials 240 100111 10.1016/S0022-3115(96)00672-1.CrossRefGoogle Scholar
Bickmore, B.R. Bosbach, D. Hochella, M.F. Charlet, L. and Rufe, E., (2001) In situ atomic force microscopy study of hectorite and nontronite dissolution: Implications for phyllosilicate edge surface structures and dissolution mechanisms American Mineralogist 86 411423 10.2138/am-2001-0404.CrossRefGoogle Scholar
Bosbach, D. Charlet, L. Bickmore, B. Hochella, M.F. Jr., (2000) The dissolution of hectorite: in-situ, real-time observations using atomic force American Mineralogist 85 12091216 10.2138/am-2000-8-914.CrossRefGoogle Scholar
Bosbach, D. Rabung, T. and Luckscheiter, B., (2002) Cm3+/Eu3+ coprecipitation with powellite (CaMoO4) during HLW glass corrosion Geochimica et Cosmochimica Acta 66 A93A93 10.1016/S0016-7037(01)00751-7.Google Scholar
Bosbach, D. Rabung, T. Brandt, F. and Fanghaenel, T., (2004) Trivalent actinide coprecipitation with powellite (CaMoO4): Secondary solid solution formation during HLW borosilicate-glass dissolution Radiochimica Acta 92 639643 10.1524/ract.92.9.639.54976.CrossRefGoogle Scholar
Bünzli, J-CG and Choppin, G.R., (1989) Lanthanide Probes in Life, Chemical and Earth Sciences Amsterdam Elsevier.Google Scholar
Carrado, K.A., (2000) Synthetic organo- and polymer-clays: preparation, characterization, and materials applications Applied Clay Science 17 123 10.1016/S0169-1317(00)00005-3.CrossRefGoogle Scholar
Carrado, K.A. Thiyagarajan, P. and Song, K., (1997) A study of organo-hectorite clay crystallization Clay Minerals 32 2940 10.1180/claymin.1997.032.1.05.CrossRefGoogle Scholar
Carrado, K.A. Zajac, G.W. Song, K. and Brenner, J.R., (1997) Crystal growth of organohectorite clay as revealed by atomic force microscopy Langmuir 13 28952902 10.1021/la961048m.CrossRefGoogle Scholar
Carrado, K.A. Xu, L. Gregory, D.M. Song, K. Seifert, S. and Botto, R.E., (2000) Crystallization of a layered silicate clay as monitored by small-angle X-ray scattering and NMR Chemistry of Materials 12 30523059 10.1021/cm000366a.CrossRefGoogle Scholar
Chapman, N.A. and Smellie, J.A.T., (1986) Introduction and summary of the workshop: natural analogues to the conditions around a final repository for high-level radioactive waste Chemical Geology 55 167173 10.1016/0009-2541(86)90021-5.CrossRefGoogle Scholar
Chung, K.H. Klenze, R. Park, K.K. Paviet-Hartmann, P. and Kim, J.I., (1998) A study of the surface sorption process of Cm(III) on silica by time-resolved laser fluorescence spectroscopy (I) Radiochimica Acta 82 215219 10.1524/ract.1998.82.special-issue.215.CrossRefGoogle Scholar
Coppin, F. Berger, G. Bauer, A. Castet, S. and Loubet, M., (2002) Sorption of lanthanides on smectite and kaolinite Chemical Geology 182 5768 10.1016/S0009-2541(01)00283-2.CrossRefGoogle Scholar
Farmer, V.C., (1974) The Infrared Spectra of Minerals London Mineralogical Society 10.1180/mono-4.CrossRefGoogle Scholar
Güven, N. and Bailey, S.W., (1988) Smectites Hydrous Phyllosilicates (Exclusive of Micas) Washington, D.C Mineralogical Society of America 497560 10.1515/9781501508998-018.CrossRefGoogle Scholar
Hartman, P. and Sunagawa, I., (1987) Modern PBC theory Morphology of Crystals Tokyo Terra Scientific Publishing Company 209253.Google Scholar
De Horrocks, W Jr. and Sudnick, D.R., (1979) Lanthanide ion probes of structure in biology. Laser-induced luminescence decay constants provide a direct measure of the number of metal-coordinated water molecules Journal of the American Chemical Society 101 334340 10.1021/ja00496a010.CrossRefGoogle Scholar
Hummel, W. Berner, U. Curti, E. Pearson, F.J. and Thoenen, T., (2002) Nagra/PSI chemical thermodynamic data base 01/01 Radiochimica Acta 90 805813 10.1524/ract.2002.90.9-11_2002.805.CrossRefGoogle Scholar
Kimura, T. and Choppin, G.R., (1994) Luminescence study on determination of the hydration number of Cm(III) Journal of Alloys and Compounds 213/214 313317 10.1016/0925-8388(94)90921-0.CrossRefGoogle Scholar
Luckscheiter, B. and Kienzler, B., (2001) Determination of sorption isotherms for Eu, Th, U and Am on the gel layer of corroded HLW glass Journal of Nuclear Materials 298 155162 10.1016/S0022-3115(01)00581-5.CrossRefGoogle Scholar
Lukscheiter, B. and Nesovic, M. (1996) Langzeitsicherheit der Endlagerung radioaktiver Abfälle: Entwicklung und Charakterisierung eines Glasproduktes für den HAWC der WAK, Forschungszentrum Karlsruhe (Long-term safety of the ultimate disposal of radioactive wastes. Development and characterization of a glass product for the HAWC of the WAK). Wissenschaftliche Berichte — Forschungszentrum Karlsruhe, FZKA 5825, pp. 1130.Google Scholar
Madejová, J. and Komadel, P., (2001) Baseline studies of The Clay Minerals Society source clays: infrared methods Clays and Clay Minerals 49 410432 10.1346/CCMN.2001.0490508.CrossRefGoogle Scholar
Malakul, P. Srinivasan, K.R. and Wang, H.Y., (1998) Metal adsorption and desorption characteristics of surfactant-modified clay complexes Industrial & Engineering Chemistry Research 37 42964301 10.1021/ie980057i.CrossRefGoogle Scholar
Mallants, D. Marivoet, J. and Sillen, X., (2001) Performance assessment of the disposal of vitrified high-level waste in a clay layer Journal of Nuclear Materials 298 125135 10.1016/S0022-3115(01)00577-3.CrossRefGoogle Scholar
Maza-Rodriguez, J. Olivera-Pastor, P. Bruque, S. and Jimenez-Lopez, A., (1992) Exchange selectivity of lanthanide ions in montmorillonite Clay Minerals 27 8189 10.1180/claymin.1992.027.1.08.CrossRefGoogle Scholar
Meunier, A. Velde, B. and Griffault, L., (1998) The reactivity of bentonites: a review. An application to clay barrier stability for nuclear waste storage Clay Minerals 33 187196 10.1180/000985598545462.CrossRefGoogle Scholar
Miller, S.E. Heath, G.R. and Gonzalez, R.D., (1982) Effects of temperature on the sorption of lanthanides by montmorillonite Clays and Clay Minerals 30 111122 10.1346/CCMN.1982.0300205.CrossRefGoogle Scholar
Miller, S.E. Heath, G.R. and Gonzalez, R.D., (1983) Effect of pressure on the sorption of Yb by montmorillonite Clays and Clay Minerals 31 1721 10.1346/CCMN.1983.0310103.CrossRefGoogle Scholar
Moore, D.M. Reynolds, R.C. Jr., (1997) X-ray Diffraction and the Identification and Analysis of Clay minerals Oxford, New York Oxford University Press.Google Scholar
Parkhurst, D.L. and Appelo, C.A.J. (1999) User’s guide to PHREEQC (version 2) — A computer program for speciation, batch-reaction, one-dimensional transport and inverse geochemical calculations. US Geological Survey.Google Scholar
Rochelle, C.A., Bateman, K., MacGregor, R., Pearce, J.M., Savage, D. and Wetton, P.D. (1996) Experimental determination of chlorite dissolution rates. Materials Research Society Symposium.Google Scholar
Shannon, R.D. and Prewitt, C.T., (1969) Effective ionic radii in oxides and fluorides Acta Crystallographica, Section B: Structural Crystallography and Crystal Chemistry B25 925946 10.1107/S0567740869003220.CrossRefGoogle Scholar
Stumpf, T. Bauer, A. Coppin, F. and Kim, J.I., (2001) Time-resolved laser fluorescence spectroscopy study of the sorption of Cm(III) onto smectite and kaolinite Environmental Science & Technology 35 36913694 10.1021/es001995o.CrossRefGoogle ScholarPubMed
Stumpf, T. Bauer, A. Coppin, F. Fanghanel, T. and Kim, J.I., (2002) Inner-sphere, outer-sphere and ternary surface complexes: a TRLFS study of the sorption process of Eu(III) onto smectite and kaolinite Radiochimica Acta 90 345349 10.1524/ract.2002.90.6.345.CrossRefGoogle Scholar
Sunagawa, I. and Sunagawa, I., (1987) Surface microtopography of crystal faces Morphology of Crystals Tokyo Terra Scientific Publishing 509553.Google Scholar
Takahashi, Y. Kimura, T. Kato, Y. Minai, Y. and Tominaga, T., (1998) Characterization of Eu(III) species sorbed on silica and montmorillonite by laser-induced fluorescence spectroscopy Radiochimica Acta 82 227232.CrossRefGoogle Scholar
Velde, B., (1995) Origin and Mineralogy of Clays Berlin, Heidelberg Springer-Verlag 10.1007/978-3-662-12648-6.CrossRefGoogle Scholar
Vidal, O. Magonthier, M.-C. Joanny, V. and Creach, M., (1995) Partitioning of La between solid and solution during the aging of Si-Al-Fe-La-Ca gels under simulated near-field conditions of nuclear waste disposal Applied Geochemistry 10 269284 10.1016/0883-2927(95)00012-9.CrossRefGoogle Scholar
Zimmer, P. Bohnert, E. Bosbach, D. Kim, J.I. and Althaus, E., (2002) Formation of secondary phases after long-term corrosion of simulated HLW glass in brine solutions at 190°C Radiochimica Acta 90 529535 10.1524/ract.2002.90.9-11_2002.529.CrossRefGoogle Scholar
Zwicky, H.U. Grambow, B. Magrabi, C. Aerne, E.T. Bradley, R. Barnes, B. Graber, T. Mohos, M. and Werme, L.O., (1989) Corrosion behavior of British Magnox waste glass in pure water Materials Research Society Symposium Proceedings 127 129136 10.1557/PROC-127-129 (Scientific Basis for Nuclear Waste Management, 12).CrossRefGoogle Scholar