Silver Zeolites: Iodide Occlusion and conversion to Sodalite – a potential 129I waste form?

Gareth P Sheppard; Joseph A Hriljac; Ewan R Maddrell; Neil C Hyatt

doi:10.1557/PROC-932-36.1

Abstract

Silver exchanged zeolites A, X and Y were used to occlude silver iodide (AgI) at 400°C. Heating to 900°C in a hot isostatic press caused decomposition of the zeolite materials and the formation of more dense phases. Silver zeolites A and X both formed sodalite, seen as a potential 129I waste form, while silver zeolite Y formed an x-ray amorphous phase containing AgI. Silver zeolite A produced the best potential waste form, a monolithic sodalite with negligible porosity.

References

REFERENCES

1. Taylor, P. –“A review of methods for immobilising ¹²⁹ I arising from a nuclear fuel reprocessing plant, with emphasis on waste-form chemistry”, Atomic Energy of Canada Limited report AECL-10163 (1990).Google Scholar

2. Barrer, R.M. - “Hydrothermal chemistry of zeolites” Wiley (1984).Google Scholar

3. Breck, D.H. – “Zeolite Molecular Sieves: Structure, chemistry, and use”, Wiley (1974).Google Scholar

4. Eiden-Assmann, S., Mater. Res. Bull., 37 (5), 875–889 (2002).Google Scholar

5. Sheppard, G.P., Thesis (MPhil), University of Birmingham (2003)Google Scholar

6. Richardson, J.W., Symposium on Scientific Basis for Nuclear Waste Management XX Dec1996, MRS Conference Proceedings 465, 395–400 (1997).1Google Scholar

7. Esh, D.W., Goff, K.M., Hirsche, K.T., Scientific Basis for Nuclear Waste Management XXII, 556, 107–113 (1999).Google Scholar

8. Matsuoka, S., Nakamura, H., Tamura, T., Takano, T. and Ito, Y., J. Nucl. Sci. and Tech. 21(11), 862–870 (1984).Google Scholar

9. Barrer, R.M. and Meier, W.M., J. Chem. Soc., 14, 299–304 (1958).Google Scholar

10. Rabo, J.A. - “alt occlusion in zeolite crystals”, Zeolite Chemistry & Catalysis (Ed. Rabo, JA), American Chemical Society Monograph, 171, 332–400 (1976).Google Scholar

11. Barrer, R.M. & Cole, J.F., J. Chem. Soc. (A), 1516–1523 (1970).Google Scholar

12. Stein, A., Ozin, G.A., MacDonald, P.M., Stucky, G.D., J. of the Amer. Chem. Soc., 114, 5171–5186 (1992).Google Scholar

13. Hyatt, N.C., Hriljac, J.A., Choudry, A., Malpass, L., Sheppard, G.P. and Maddrell, E.R., Scientific Basis for Nuclear Waste Management XXVII, 807, 359–364 (2004).Google Scholar

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Garino, Terry J. Nenoff, Tina M. Krumhansl, James L. and Rademacher, David 2010. Materials Challenges in Alternative and Renewable Energy. Vol. 224, Issue. , p. 305.

Maddrell, Ewan Gandy, Amy and Stennett, Martin 2014. The durability of iodide sodalite. Journal of Nuclear Materials, Vol. 449, Issue. 1-3, p. 168.

Xiong, Yongliang 2014. A Pitzer model for the Na–Al(OH)4–Cl–OH system and solubility of boehmite (AlOOH) to high ionic strength and to 250°C. Chemical Geology, Vol. 373, Issue. , p. 37.

Yang, Jae Hwan Cho, Yong-Jun Shin, Jin Myeong and Yim, Man-Sung 2015. Bismuth-embedded SBA-15 mesoporous silica for radioactive iodine capture and stable storage. Journal of Nuclear Materials, Vol. 465, Issue. , p. 556.

Wang, Jianwei 2015. Incorporation of iodine into apatite structure: a crystal chemistry approach using Artificial Neural Network. Frontiers in Earth Science, Vol. 3, Issue. ,

Xiong, Yongliang 2016. Solubility constants of hydroxyl sodalite at elevated temperatures evaluated from hydrothermal experiments: Applications to nuclear waste isolation. Applied Geochemistry, Vol. 74, Issue. , p. 138.

Asmussen, R. Matthew Neeway, James J. Lawter, Amanda R. Wilson, Andrew and Qafoku, Nikolla P. 2016. Silver-based getters for 129I removal from low-activity waste. Radiochimica Acta, Vol. 104, Issue. 12, p. 905.

Matyáš, Josef Canfield, Nathan Sulaiman, Sannoh and Zumhoff, Mac 2016. Silica-based waste form for immobilization of iodine from reprocessing plant off-gas streams. Journal of Nuclear Materials, Vol. 476, Issue. , p. 255.

Cao, Charles Chong, Saehwa Thirion, Lynn Mauro, John C. McCloy, John S. and Goel, Ashutosh 2017. Wet chemical synthesis of apatite-based waste forms – A novel room temperature method for the immobilization of radioactive iodine. Journal of Materials Chemistry A, Vol. 5, Issue. 27, p. 14331.

Li, Dien Kaplan, Daniel I. Sams, Allison Powell, Brian A. and Knox, Anna S. 2018. Removal capacity and chemical speciation of groundwater iodide (I−) and iodate (IO3−) sequestered by organoclays and granular activated carbon. Journal of Environmental Radioactivity, Vol. 192, Issue. , p. 505.

Li, Dien Kaplan, Daniel I. Price, Kimberly A. Seaman, John C. Roberts, Kimberly Xu, Chen Lin, Peng Xing, Wei Schwehr, Kathleen and Santschi, Peter H. 2019. Iodine immobilization by silver-impregnated granular activated carbon in cementitious systems. Journal of Environmental Radioactivity, Vol. 208-209, Issue. , p. 106017.

Zhang, Zelong Ebert, William L. Yao, Tiankai Lian, Jie Valsaraj, Kalliat T. and Wang, Jianwei 2019. Chemical Durability and Dissolution Kinetics of Iodoapatite in Aqueous Solutions. ACS Earth and Space Chemistry, Vol. 3, Issue. 3, p. 452.

Hassan, Muhmood ul Venkatesan, Suriya and Ryu, Ho Jin 2020. Non-volatile immobilization of iodine by the cold-sintering of iodosodalite. Journal of Hazardous Materials, Vol. 386, Issue. , p. 121646.

Chong, Saehwa Riley, Brian J. Asmussen, R. Matthew Fujii Yamagata, Alessandra L. Marcial, José Lee, Sungsik and Burns, Carolyne A. 2022. Iodine Capture with Metal-Functionalized Polyacrylonitrile Composite Beads Containing Ag0, Bi0, Cu0, or Sn0 Particles. ACS Applied Polymer Materials, Vol. 4, Issue. 12, p. 9040.

Riley, Brian J. Chong, Saehwa Schmid, Julian Marcial, José Nienhuis, Emily T. Bera, Mrinal K. Lee, Sungsik Canfield, Nathan L. Kim, Sungmin Derewinski, Miroslaw A. and Motkuri, Radha Kishan 2022. Role of Zeolite Structural Properties toward Iodine Capture: A Head-to-head Evaluation of Framework Type and Chemical Composition. ACS Applied Materials & Interfaces, Vol. 14, Issue. 16, p. 18439.

Lin, Shijian Wang, Menghui Hao, Yan Zhang, Kuibao Li, Yuhong and Yang, Dongyan 2022. Synthesis, structure and thermal stability of iodine-contained sodalites Na8(AlSiO4)6Cl2-I (x = 0–2) for 129I immobilization. Journal of Alloys and Compounds, Vol. 908, Issue. , p. 164617.

Jiao, Yuhan Liu, Yi Zhang, Shengdong Zhang, Zhentao Feng, Yaxin Zhang, Yuchuan and Wei, Guilin 2023. The effects of dry grinding and wet grinding on synthesizing iodosodalite. Journal of Solid State Chemistry, Vol. 320, Issue. , p. 123832.

Yadav, Anjali Chong, Saehwa Riley, Brian J. McCloy, John S. and Goel, Ashutosh 2023. Iodine Capture by Ag-Loaded Solid Sorbents Followed by Ag Recycling and Iodine Immobilization: An End-to-End Process. Industrial & Engineering Chemistry Research, Vol. 62, Issue. 8, p. 3635.

Wang, Jianwei Ghosh, Dipta B. and Zhang, Zelong 2023. Computational Materials Design for Ceramic Nuclear Waste Forms Using Machine Learning, First-Principles Calculations, and Kinetics Rate Theory. Materials, Vol. 16, Issue. 14, p. 4985.

Chukanov, Nikita V. and Aksenov, Sergey M. 2024. Structural Features, Chemical Diversity, and Physical Properties of Microporous Sodalite-Type Materials: A Review. International Journal of Molecular Sciences, Vol. 25, Issue. 18, p. 10218.

Article contents

Silver Zeolites: Iodide Occlusion and conversion to Sodalite – a potential 129I waste form?

Abstract

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Article contents

Silver Zeolites: Iodide Occlusion and conversion to Sodalite – a potential 129I waste form?

Abstract

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References

REFERENCES

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