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Separation of 137Cs from Acidic Nuclear Waste Simulant via an Engineered Inorganic Ion Exchanger

Published online by Cambridge University Press:  17 March 2011

T.J. Tranter*
Affiliation:
Idaho National Engineering and Environmental Laboratory, P.O. Box 1625, Idaho Falls, ID USA, 83415
T.A. Vereshchagina
Affiliation:
Institute of Chemistry and Chemical Technologies, 42 K. Marx St., Krasnoyarsk, Russia, 660049
A.G. Anshits
Affiliation:
Institute of Chemistry and Chemical Technologies, 42 K. Marx St., Krasnoyarsk, Russia, 660049
E. Fomenko
Affiliation:
Institute of Chemistry and Chemical Technologies, 42 K. Marx St., Krasnoyarsk, Russia, 660049
A.S. Aloy
Affiliation:
V.G. Khlopin Radium Institute, 2-nd Murinskiy Ave., St. Petersburg, Russia, 194021
N.V. Sapozhnikova
Affiliation:
V.G. Khlopin Radium Institute, 2-nd Murinskiy Ave., St. Petersburg, Russia, 194021
*
Corresponding author: email [email protected]
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Abstract

An engineered ion exchange material has been prepared for the specific purpose of removing radioactive cesium from acidic waste. Separating the fission product 137Cs from the bulk of the nuclear waste stream is often advantageous because, after typical cooling times, this isotope is usually the primary source of gamma radiation dose. The engineered ion exchanger was prepared using ammonium molybdophosphate impregnated into hollow glass crystalline microspheres. The microspheres or cenospheres, are refractory compounds of silica and alumina that are derived from the fly ash produced in coal combustion. This paper describes equilibrium experiments that were conducted with the engineered ion exchanger and a simulated acidic waste solution. These tests indicate that the new material has a high capacity and selectivity for cesium in these matrices.

Type
Research Article
Copyright
Copyright © Materials Research Society 2004

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References

1. Buchwald, H., Thistlewaite, W.P., J. Inorg. Nucl. Chem., 5, p. 341, (1957).Google Scholar
2. Smit, J. van R., Inorganic Ion Exchangers in Chemical Analysis, Qureshi, M. and Varshney, K.G. (Eds.), pp. 6169, CRC Press, Boston, 1991.Google Scholar
3. Suss, M., Pfrepper, F., Radiochimica Acta, 29, pp. 3340, (1981).Google Scholar
4. Tranter, T.J., Herbst, R.S., Todd, T.A., Olson, A.L., Eldredge, H.B., Advances in Environmental Research, 6, pp. 107121, (2002).Google Scholar
5. Tranter, T.J., Herbst, R.S., Todd, T.A., Adsorption, 8 (4), pp. 291299, (2002).Google Scholar
6.U.S. Patent No's. 6,444,162, 6,472,579, 6,667,261.Google Scholar
7.Case No. 97,170. U.S. Patent filed March, 2003.Google Scholar
8. Tranter, T.J., Aloy, A.S., Sapozhnikova, N.V., Tretyakov, A.A., Anshits, A.G., Knecht, D.A., Todd, T.A., Macheret, J., Scientific Basis for Nuclear Waste Management XXV, Vol. 713, pp. 907913, (2002).Google Scholar
9. , Brunauer, J. Am. Chem. Soc., 62, p.1723, (1940).Google Scholar
10. Chemical Engineers' Handbook, Perry, R.H., Chilton, C.H., Eds.; McGraw-Hill, New York, 7th ed., PP. 16–12-13, (1997).Google Scholar