2020
DOI: 10.1111/jace.17293
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Hot Isostatically Pressed (HIPed) fluorite glass‐ceramic wasteforms for fluoride molten salt wastes

Abstract: Molten pyroprocessing salts can be used to dissolve used nuclear fuel from a reactor allowing recovery of the actinides. Previously, ANSTO have demonstrated hot isostatically pressed (HIPed) sodalite glass‐ceramic wasteforms for eutectic (Li,K)Cl salts containing fission products, but this system cannot be used for the analogous molten alkali fluoride salts (eg, FLiNaK), which have utility in the application of the next generation of nuclear reactors. In this work, a novel glass‐ceramic composite wasteform has… Show more

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Cited by 12 publications
(8 citation statements)
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“…HIP is an attractive processing option for the consolidation of radioactive waste with the ability to process a wide range of waste streams, targeting minimal secondary waste generation and minimal volatile losses during processing 4,11 . HIPed wasteforms have been demonstrated for a variety of problematic wastes, for example, uranium‐rich radioactive wastes arising from Mo‐99 production, 12,13 radioiodine from the PUREX process, 14 and fluoride molten salt wastes 15 . These wasteforms produced by HIPing can be either full ceramic (C), GC, or glass (G) and are tailored to the waste stream chemistry.…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation
“…HIP is an attractive processing option for the consolidation of radioactive waste with the ability to process a wide range of waste streams, targeting minimal secondary waste generation and minimal volatile losses during processing 4,11 . HIPed wasteforms have been demonstrated for a variety of problematic wastes, for example, uranium‐rich radioactive wastes arising from Mo‐99 production, 12,13 radioiodine from the PUREX process, 14 and fluoride molten salt wastes 15 . These wasteforms produced by HIPing can be either full ceramic (C), GC, or glass (G) and are tailored to the waste stream chemistry.…”
Section: Introductionmentioning
confidence: 99%
“…4,11 HIPed wasteforms have been demonstrated for a variety of problematic wastes, for example, uranium-rich radioactive wastes arising from Mo-99 production, 12,13 radioiodine from the PUREX process, 14 and fluoride molten salt wastes. 15 These wasteforms produced by HIPing can be either full ceramic (C), GC, or glass (G) and are tailored to the waste stream chemistry. For the management of Pu-bearing waste material, leading candidates currently being considered are zirconolite-or pyrochlorebased full C wasteforms or GC wasteforms, fabricated by HIPing.…”
Section: Introductionmentioning
confidence: 99%
“…This study [Raman, 1998] is a good example of designing the additives to produce a set of targeted crystalline phases. Recently fluorapatite phases have been created by two-step sintering of iron phosphate glass with SrF 2 , in an effort to explore waste forms for immobilizing the halides in molten salt reactors [Zhou et al, 2021]; other researchers, however, have emphasized the low waste loading of fluorine in this scheme [Gregg et al, 2020b]. GC for dental applications have been demonstrated from phosphate glasses with Sr phosphates and Sr-and Ca-fluorapatite plus xenotime and monazite [Ritzberger et al, 2013] or with chlorapatite from aluminosilicate glasses [Chen et al, 2014].…”
Section: Phosphatesmentioning
confidence: 99%
“…One additional option for creating a stable waste form from halide salts is to segregate the halide into a crystalline halide phase embedded within a high-durability glass phase that contains FP and potentially actinide oxides. Trapping the F atoms in a stable alkali fluoride phase within an aluminoborosilicate glass is the basis for the "synroc" process developed at the Australian Nuclear Science and Technology Organization (ANSTO) [97]. The ANSTO process grinds the fuel salt into a powder and mixes it with glass, forming oxides, calcining, and then hot isostatically pressing the material.…”
Section: Integrated Waste Processingmentioning
confidence: 99%