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The Possibility for Microbially Influenced Degradation of Cement Solidified Low-Level Radioactive Waste Forms

Published online by Cambridge University Press:  01 January 1992

Robert D. Rogers ,
Melinda A. Hamilton  and
John W. Mcconnell
Robert D. Rogers
Affiliation:
Idaho National Engineering Laboratory/EG&G Idaho, Inc., P. 0. Box 1625, Idaho Falls, ID 83415-2203
Melinda A. Hamilton
Affiliation:
Idaho National Engineering Laboratory/EG&G Idaho, Inc., P. 0. Box 1625, Idaho Falls, ID 83415-2203
John W. Mcconnell
Affiliation:
Idaho National Engineering Laboratory/EG&G Idaho, Inc., P. 0. Box 1625, Idaho Falls, ID 83415-2203
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Abstract

The Nuclear Regulatory Commission (NRC) regulations 10 CFR Part 61, “Licensing Requirements for Land Disposal of Radioactive Waste,” regulate the disposal of radioactive waste and provides, among other stipulations, that class B and C low-level radioactive waste (LLW) be stabilized. This is intended to ensure that solidified waste does not structurally degrade and cause subsidence in the disposal unit's cover system. It is reasoned that deterioration of the waste form could adversely effect the stability of the burial site and lead to the release of radionuclides to the environment. Because of its apparent structural integrity, cement has been widely used as a binder to solidify LLW. However, the resulting preparations called pozzolanic cements are susceptible to failure due to the actions of stress and environment.

This paper presents data from the literature that document the significance of biologically mediated chemical attack on concrete, in general. Concrete is susceptible to aggressive reaction with acids (both mineral and organic) of natural and anthropogenic origin. If persistent, such reactions ultimately lead to structural failure. Groups of microorganisms have been identified that are capable of metabolically converting organic and inorganic substrates into organic and mineral acids.

The literature supports the conclusions that acid-producing bacteria of one type or another could be prevalent in all soils, even at depths expected for burial of LLW. Given the appropriate conditions of micro-environment and suitable substrate for growth, these bacteria will create conditions conducive to concrete deterioration. Growth substrates used by acid-producing bacteria (i.e., ammonia compounds, other reduced nitrogen compounds, sulfur and reduced sulfur compounds, reduced iron compounds, as well as organic carbon) could be naturally present in the disposal environment or be provided by the contents of the waste form.

Sufficient evidence is presented which demonstrates the potential for microbially-influenced deterioration of cement-solidified LLW. These data are the basis for the NRC initiating the development of appropriate tests to determine the resistance of cement-solidified LLW to microbiologically induced degradation.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 294: Symposium V – Scientific Basis for Nuclear Waste Management XVI , 1992 , 261
Copyright
Copyright © Materials Research Society 1993

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References

REFERENCES

1. NRC, Technical Position on Waste Form, Rev. 1, January, 1991.Google Scholar
2. Clifton, J. R., Knab, L. I., 1989. Service life of concrete. NRC publication NUREG/CR-5466.Google Scholar
3. Rogers, R. D., McConnell, J. W., 1988. Biodegradation testing of TMI-2 EPICOR-II waste forms. NRC publication NUREG/CR-5137.Google Scholar
4. American Society for Testing Materials, “Standard Practice for Determining Resistance of Synthetic Polymeric Materials to Fungi,” ASTM G21-70, 1981 Annual Book of Standards, Part 35.Google Scholar
5. American Society for Testing Materials, “Standard Practice for Determining Resistance of Plastic to Bacteria,” ASTM G22-76, 1981 Annual Book of Standards, Part 35.Google Scholar
6. Sand, W., Bock, E.. 1982. Der einflub von C-und N-guellen auf die induktion des nitrit oxidierenden systems und auf den PHB-gehalt von Nitrobacter agilis Kl. Mitt. Inst. Allg. Bot. Hamburg 18:61-70.Google Scholar
7. Bock, E., Sand, M., Meincke, B., Wolters, B., Ahlers, B., Meyer, C., Sameluck, F.. 1988. Biologically inducted corrosion of natural stones - Strong contamination of monument with nitrifying organisms. in Biodeterior (Pap. Int. Bodeterior. Symp.). Houghton, D. R., Smith, R. N., Eggins, H. O. W. (eds.).Google Scholar
8. Karavaiko, G. I., Zherebyat'eva, T. V.. 1989. Bacterial corrosion of concrete. Kokl Adad Nauk SSSR 306 (2):477-481.Google Scholar
9. Neville, A. M. 1981. Properties of Concrete. Longmand Scientific and Technical Publishers.Google Scholar
10. Sand, W., Bock, E.. 1988. Biogenic sulfuric acid attack in sewage systems. In: 7th International Biodeterioration Symposium: Cambridge England. Houghton, D. R., Smith, R. N., Eggins, H. O. W. (eds). pp 113117.Google Scholar
11. Islander, R. L., Devinny, J. S., Mansfeld, R., Postyn, A., Shih, H.. 1991. Microbial ecology of crown corrosion in sewers. Jour. Environ. Engin. 117:751-770.Google Scholar
12. Mori, T., Nonada, T., Tazake, K., Koga, M., Hikosaka, Y., Hoda, S.. 1992. Interactions of nutrients, moisture and pH on microbial corrosion of concrete sewer pipes. Wat. Res. 26:29-37.Google Scholar
13. Sand, W., Bock, E.. 1984. Concrete corrosion in the Hamburg sewer system. Environ. Techn. Let. 5:517-528.Google Scholar
14. Kuenen, J. G., Tuovinen, O. H.. 1981. The Genera Thiobacillus and Thiomicrospira. In: The Prokaryotes: A Handbook on Habitats, Isolation, and Identification of Bacteria. Vol. 1. Starr, M. P., Stolp, H., Truper, H. G., Belows, A., Schlegel, H. G. (eds). Springer - Verlag, New York.Google Scholar
15. Alexander, M. 1977. Introduction to Soil Microbiology. John Wiley and Sons Inc. pp. 476.Google Scholar
16. Bock, E. 1987. Biologically induced corrosion of natural stone - Strong attack by nitrifiers. Bautenschutz Bausanierung 10 (1):24-27.Google Scholar
17. Diercks, M., Wand, W., Bock, E.. 1991. Microbial corrosion of concrete. Experientia 47:514-516.Google Scholar
18. Hall, G. R. 1989. Control of microbiologically induced corrosion of concrete in wastewater collection and treatment systems. Material Perf. 28(10):45-49.Google Scholar
19. Dunk, M. 1991. Influences of microbiology on nuclear waste disposal. HMIP Department of the Environment. DOE/HMIP/RR/91/033.Google Scholar