Titanate Ceramics for the Immobilization of Sodium‐Bearing High‐Level Nuclear Waste

WILLIAM J. BUYKX; KATE HAWKINS; DESMOND M. LEVINS; HISAYOSHI MITAMURA; ROGER St C. SMART; GEOFFRY T. STEVENS; KENNETH G. WATSON; DAVID WEEDON; TIMOTHY J. WHITE

doi:10.1111/j.1151-2916.1988.tb06388.x

Titanate Ceramics for the Immobilization of Sodium‐Bearing High‐Level Nuclear Waste

WILLIAM J. BUYKX^*, KATE HAWKINS, DESMOND M. LEVINS, HISAYOSHI MITAMURA, ROGER St C. SMART, GEOFFRY T. STEVENS, KENNETH G. WATSON, DAVID WEEDON, TIMOTHY J. WHITE

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

38 Citations (Scopus)

Abstract

The phase chemistries and microstructures of titanate‐based ceramics containing simulated high‐level nuclear waste with varying sodium contents were compared. Incorporation of relatively low sodium levels (∼0.9 wt% Na₂O) resulted in more complex phase assemblages. The principal hosts for sodium were hibonite and freudenbergite, and, when iron and sodium were present in combination, loveringite was also stabilized. During fabrication, oxygen potential was controlled by Ti‐TiO₂ or TiH₂‐Ti₃O₅ solid‐state buffers. These metal and hydride oxygen getters behaved similarly, neither disturbing the phase assemblages nor significantly altering the partitioning of waste elements between radiophases. It is believed that the hydrothermal stability of the sodium‐bearing ceramics (containing up to 2.7 wt% Na₂O) will be comparable to sodium‐free material, since less durable sodium‐rich phases are encapsulated in a resistant matrix. Extensive formation of glassy phases may cause embrittlement at higher sodium loadings.

Original language	English
Pages (from-to)	678-688
Number of pages	11
Journal	Journal of the American Ceramic Society
Volume	71
Issue number	8
DOIs	https://doi.org/10.1111/j.1151-2916.1988.tb06388.x
Publication status	Published - Aug 1988
Externally published	Yes

ASJC Scopus Subject Areas

Ceramics and Composites
Materials Chemistry

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10.1111/j.1151-2916.1988.tb06388.x

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BUYKX, WILLIAM. J., HAWKINS, KATE., LEVINS, DESMOND. M., MITAMURA, HISAYOSHI., SMART, ROGER. S. C., STEVENS, GEOFFRY. T., WATSON, KENNETH. G., WEEDON, DAVID., & WHITE, TIMOTHY. J. (1988). Titanate Ceramics for the Immobilization of Sodium‐Bearing High‐Level Nuclear Waste. Journal of the American Ceramic Society, 71(8), 678-688. https://doi.org/10.1111/j.1151-2916.1988.tb06388.x

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title = "Titanate Ceramics for the Immobilization of Sodium‐Bearing High‐Level Nuclear Waste",

abstract = "The phase chemistries and microstructures of titanate‐based ceramics containing simulated high‐level nuclear waste with varying sodium contents were compared. Incorporation of relatively low sodium levels (∼0.9 wt% Na2O) resulted in more complex phase assemblages. The principal hosts for sodium were hibonite and freudenbergite, and, when iron and sodium were present in combination, loveringite was also stabilized. During fabrication, oxygen potential was controlled by Ti‐TiO2 or TiH2‐Ti3O5 solid‐state buffers. These metal and hydride oxygen getters behaved similarly, neither disturbing the phase assemblages nor significantly altering the partitioning of waste elements between radiophases. It is believed that the hydrothermal stability of the sodium‐bearing ceramics (containing up to 2.7 wt% Na2O) will be comparable to sodium‐free material, since less durable sodium‐rich phases are encapsulated in a resistant matrix. Extensive formation of glassy phases may cause embrittlement at higher sodium loadings.",

author = "BUYKX, {WILLIAM J.} and KATE HAWKINS and LEVINS, {DESMOND M.} and HISAYOSHI MITAMURA and SMART, {ROGER St C.} and STEVENS, {GEOFFRY T.} and WATSON, {KENNETH G.} and DAVID WEEDON and WHITE, {TIMOTHY J.}",

year = "1988",

month = aug,

doi = "10.1111/j.1151-2916.1988.tb06388.x",

language = "English",

volume = "71",

pages = "678--688",

journal = "Journal of the American Ceramic Society",

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number = "8",

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BUYKX, WILLIAMJ, HAWKINS, KATE, LEVINS, DESMONDM, MITAMURA, HISAYOSHI, SMART, ROGERSC, STEVENS, GEOFFRYT, WATSON, KENNETHG, WEEDON, DAVID & WHITE, TIMOTHYJ 1988, 'Titanate Ceramics for the Immobilization of Sodium‐Bearing High‐Level Nuclear Waste', Journal of the American Ceramic Society, vol. 71, no. 8, pp. 678-688. https://doi.org/10.1111/j.1151-2916.1988.tb06388.x

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AU - BUYKX, WILLIAM J.

AU - HAWKINS, KATE

AU - LEVINS, DESMOND M.

AU - MITAMURA, HISAYOSHI

AU - SMART, ROGER St C.

AU - STEVENS, GEOFFRY T.

AU - WATSON, KENNETH G.

AU - WEEDON, DAVID

AU - WHITE, TIMOTHY J.

PY - 1988/8

Y1 - 1988/8

N2 - The phase chemistries and microstructures of titanate‐based ceramics containing simulated high‐level nuclear waste with varying sodium contents were compared. Incorporation of relatively low sodium levels (∼0.9 wt% Na2O) resulted in more complex phase assemblages. The principal hosts for sodium were hibonite and freudenbergite, and, when iron and sodium were present in combination, loveringite was also stabilized. During fabrication, oxygen potential was controlled by Ti‐TiO2 or TiH2‐Ti3O5 solid‐state buffers. These metal and hydride oxygen getters behaved similarly, neither disturbing the phase assemblages nor significantly altering the partitioning of waste elements between radiophases. It is believed that the hydrothermal stability of the sodium‐bearing ceramics (containing up to 2.7 wt% Na2O) will be comparable to sodium‐free material, since less durable sodium‐rich phases are encapsulated in a resistant matrix. Extensive formation of glassy phases may cause embrittlement at higher sodium loadings.

AB - The phase chemistries and microstructures of titanate‐based ceramics containing simulated high‐level nuclear waste with varying sodium contents were compared. Incorporation of relatively low sodium levels (∼0.9 wt% Na2O) resulted in more complex phase assemblages. The principal hosts for sodium were hibonite and freudenbergite, and, when iron and sodium were present in combination, loveringite was also stabilized. During fabrication, oxygen potential was controlled by Ti‐TiO2 or TiH2‐Ti3O5 solid‐state buffers. These metal and hydride oxygen getters behaved similarly, neither disturbing the phase assemblages nor significantly altering the partitioning of waste elements between radiophases. It is believed that the hydrothermal stability of the sodium‐bearing ceramics (containing up to 2.7 wt% Na2O) will be comparable to sodium‐free material, since less durable sodium‐rich phases are encapsulated in a resistant matrix. Extensive formation of glassy phases may cause embrittlement at higher sodium loadings.

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Titanate Ceramics for the Immobilization of Sodium‐Bearing High‐Level Nuclear Waste

Abstract

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