Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-28T05:40:38.961Z Has data issue: false hasContentIssue false

Microstructural Characterization of U Coprecipitated Phases Formed in Bentonic-Granitic Groundwater and under Anoxic Conditions

Published online by Cambridge University Press:  19 October 2011

Javier Quinones
Affiliation:
[email protected], CIEMAT, energy, Avda. Complutense 22. E. 12-S1-23, Madrid, 28040., Spain, +34 913466290, +34 913466233
Eduardo Iglesias
Affiliation:
[email protected], CIEMAT, Energy, Avda. Complutense 22, Madrid, 28040, Spain
Jose M. Cobo
Affiliation:
[email protected], CIEMAT, Energy, Avda. Complutense 22, Madrid, 28040, Spain
Aurora Martinez Esparza
Affiliation:
[email protected], Enresa, Emilio Vargas, 7, Madrid, 28043, Spain
Jose Maria Gomez de Salazar
Affiliation:
[email protected], UCM, Materials Science, Avda. Complutense s/n, Madrid, 28040, Spain
Get access

Abstract

For improving the accuracy of the performance assessment studies related to the spent fuel safety under storage conditions it is necessary to develop a new matrix alteration model. These models must be based on laboratory experiences and they should be capable to extrapolate to storing environmental conditions. Most of recently models developed included the oxidation and dissolution process of the spent fuel matrix, but the influence of a possible process of secondary phase formation over the spent fuel surface is not taken into account yet. This is a key process that could produce a reduction of the matrix dissolution rate, radiation shielding behaviour; however, the surface precipitation of the secondary phase could induce a localized corrosion process, which in this case dissolution rate of the spent fuel would be increased. This paper is focussed on microstructural characterization of secondary phases formed in coprecipitation experiments performed under anoxic conditions in granitic-bentonitic simulated groundwater. In order to simulate the influence of the container material, the coprecipitation experiments were performed in absence and presence of iron powder. The solid phases formed were characterized using the following techniques: XRD; SEM-EDX and TEM-EDX. The XRD diffraction pattern showed that under anoxic conditions a mixture of phases were obtained (sodium and potassium uranate and schoepite), whereas uranate phases were detected when only iron was present. The characterization study indicates that the U secondary phase formed (under reducing conditions and presence of iron powder) growth from iron surface. The crystal size of the secondary phase is independent of the presence of iron powder (and it is always less than 3 μm). Furthermore, the microstructural study showed the growing of U phases over iron powder.

Type
Research Article
Copyright
Copyright © Materials Research Society 2007

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. MITYC, “Sexto plan general de residuos radiactivos,” Ministerio de industria, turismo y comercio. Gobierno de España, Madrid 23 de Junio 2006.Google Scholar
2. Esparza, A. Martínez, Quinones, J., Gago, J. A., Cáceres, J., Iglesias, E., Huebra, A. González de la, Pablo, J. de, Casas, I., Clarens, F.,. Giménez, J., Rovira, M., Cera, E., Merino, J., Brunoy, J. Grambow, B., “D14. MAM Sensitivity Analysis and Applicability. WP4: Matrix Model Construction. Contract N° FIKW–CT–2001–20192 SFS,” en European Commission. 5th Euratom Framework Programme 1998–2002. Key Action: Nuclear Fission, A. Martínez Esparza y QuiÒones, J., Eds. Madrid, 2004, pp. 54.Google Scholar
3. Quiñones, J., Iglesias, E., Esparza, A. Martínez, Merino, J., Cera, E., Bruno, J., De Pablo, J., Casas, I., Clarens, J. Giménez, F. y Rovira, M., “Modelling of the spent fuel dissolution rate evolution for repository conditions. Matrix Alteration Model results and sensitivity analysis,” en Scientific Basis for Nuclear Waste Management Material Research Society. Accepted for publication, 2006.Google Scholar
4. Quiñones, J., Grambow, B., Loida, A. y Geckeis, H., “Coprecipitation phenomena in spent fuel dissolution. Part I: Experimental procedure and initial results on trivalent ion behaviour,” J. Nucl. Mater., vol.238, pp. 38, 1996.Google Scholar
5. Quiñones, J., Huebra, A. González de la y Esparza, A. Martínez, “Coprecipitation experiments using simulated spent fuel solution in the presence of metallic iron in synthetic bentoniticgranitic water under oxidising conditions,” en Scientific Basis for Nuclear Waste Management XXVIII, vol.824, Mat. Res. Soc. Symp. Proc., Stroes-Gascoyne, S., Hanchar, J. y Browning, L., Eds. San Francisco. USA: Material Research Society, 2004, pp. 425430.Google Scholar
6. Quiñones, J., Huebray, A. González de la Esparza, A. Martínez, “Effect of corroded engeniering barrier on the alteration process of the spent fuel matrix under repository conditions,Geochimica et Cosmochimica Acta, vol.68, pp. 113, 2004.Google Scholar
7. Martinez, B., Melon, A. y Valladares, J., “Preparation of a Synthetic Bentonitic-Granitic water. Specific procedure,” en Informes Técnicos, vol. PR-X8–01. Madrid: Ciemat, 1996.Google Scholar
8. JCPDS - ICDD, “PCPDFWIN,” 2.02 ed: International Centre for Diffraction Data, 1999.Google Scholar