Tungsten bronze-based nuclear waste form ceramics. Part 2: Conversion of granular microporous tungstate–polyacrylonitrile (PAN) composite adsorbents to leach resistant ceramics

Conversion of a granular molybdenum-doped, hexagonal tungsten bronze (MoW–HTB)–polyacrylonitrile (PAN) composite adsorbent to a leach resistant ceramic waste form capable of immobilizing adsorbed Cs + and Sr 2+ has been achieved by heating in air at temperatures in the range 600–1200 °C. Thermal tre...

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Bibliographic Details
Published in:Journal of nuclear materials 2006-11, Vol.358 (2), p.151-163
Main Authors: Griffith, Christopher S., Sebesta, Ferdinand, Hanna, John V., Yee, Patrick, Drabarek, Elizabeth, Smith, Mark E., Luca, Vittorio
Format: Article
Language:English
Subjects:
Applied sciences
Energy
Exact sciences and technology
Fuels
Nuclear fuels
Preparation and processing of nuclear fuels
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Summary:Conversion of a granular molybdenum-doped, hexagonal tungsten bronze (MoW–HTB)–polyacrylonitrile (PAN) composite adsorbent to a leach resistant ceramic waste form capable of immobilizing adsorbed Cs + and Sr 2+ has been achieved by heating in air at temperatures in the range 600–1200 °C. Thermal treatment of the Cs- and Sr-loaded composite material at 1000 °C was sufficient to invoke a 60% reduction in volume of the composite while still retaining its spherical morphology. Cs-133 MAS NMR studies of this sample suite at 9.4 T and 14.1 T showed that multiple Cs sites are present throughout the entire thermal treatment range. Scanning electron microscopy investigations of the phase assemblages resulting from thermal treatment demonstrated that the full complement of Cs, and the majority of Sr, partitions into HTB phases (A 0.16–0.3MO 3; A = Cs +, Sr 2+ and Na +; M = Mo, W). The potentially reducing conditions resulting from the removal of the PAN matrix or the presence of high concentrations of Na + relative to either Cs + or Sr 2+ does not retard the formation of the high temperature HTB phases. The fraction of Cs + and Sr 2+ leached from the tungstate phase assemblages was superior or comparable with cesium hollandite (Cs 0.8Ba 0.4Ti 8O 18; f = ≈8 × 10 −5; rate =
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2006.06.018