Solution‐Derived, Chloride‐Containing Minerals as a Waste Form for Alkali Chlorides

Riley, Brian J.; Crum, Jarrod V.; Matyáš, Josef; McCloy, John S.; Lepry, William C.

doi:10.1111/j.1551-2916.2012.05363.x

Cited by 25 publications

(22 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…除了设计 ACWF, 近几年关于 CWF 的研究还集中在 CWF 容器设计和实验规模扩大上。INL 的 Bateman 等 [20][21] [24] Fig. 3 Schematic of the simplified solution-based process [24] 这种方法对于高 [30] 。SAP 产品与熔融盐接触时, 磷酸盐的化学键会发生断裂引发反应。在反应过程中, 金属元素与复合材料中的铝硅酸盐、铝磷酸盐和磷酸盐发生化学相互作用, 生成具有高热稳定性的金属化合物 [31][32] 。反应方程式如下 [30] : 图 4 KAERI 凝固工艺流程脱氯-氯化反应系统 Fig. 4 [32] 。U-SAP 固化体在 650~1150 ℃反应和固结之后, 结构没有很大变化, 仍保持了其亚微米级的结构尺寸。KAERI 正在计划进行一系列实验以研究 U-SAP 固化体的形态、元素分布、热性质和化学/ 物理性质等 [33]…”

Section: 扩大规模的 Cwf 固化体研究unclassified

Ceramic Solidification of Salt-containing Waste from Pyrochemical Reprocessing of Spent Nuclear Fuel

Chai¹,

Shi²

2019

Journal of Inorganic Materials

View full text Add to dashboard Cite

For the future advanced nuclear fuel cycle system, pyrochemical technology based on molten salt electrolysis is generally considered to be one of the most promising and reliable reprocessing technologies. The salt-containing waste generated in each step of the pyrochemical process needs to be converted into a ceramic waste form, which can be stably disposed in a long term manner in deep geological repository. This is of pivotal importance for the scale-up and industrialization of molten salt electrolysis based pyrochemical processing. In this review, the current research progresses of ceramic solidification technology in main nuclear energy countries with respect to salt-containing wastes were summarized and reviewed, with emphasis on ceramic solidifications of salt-containing wastes from electro-reduction process in LiCl-based salt and electro-refining process in LiCl-KCl salt. In addition, future perspectives in this field are also given.

show abstract

Section: 扩大规模的 Cwf 固化体研究unclassified

Ceramic Solidification of Salt-containing Waste from Pyrochemical Reprocessing of Spent Nuclear Fuel

Chai¹,

Shi²

2019

Journal of Inorganic Materials

View full text Add to dashboard Cite

show abstract

“…The purpose of adding a glass binder to sodalite (and for most of the mineral forms) is that it helps reduce the surface area during consolidation, thus improving the chemical durability of the final Tc-laden waste form. This approach has been used successfully to bind sodalite for the baseline ceramic waste form used to immobilize spent electrochemical salt wastes (Bateman et al 2007;Lepry et al 2013;Riley et al 2012). In these studies, the addition of the glass binder was used to decrease the porosity of the final product and to immobilize the fission products from the salt waste that could not be incorporated into the mineral structure of the sodalite, e.g., lanthanide and alkaline earth chlorides.…”

Section: Glass-bonded Sodalite Waste Formmentioning

confidence: 99%

Options for the Separation and Immobilization of Technetium

Serne¹,

Crum²,

Riley³

et al. 2016

Self Cite

View full text Add to dashboard Cite

“…An alternative way to making the sodalite is with a solution-based approach [3][4][5]. One solution-based method [3,4] used colloidal silica, NaAlO2, and a salt solution to make sodalite at near-room temperature (65 °C), and those samples were referred to as S5A pellets. This process had some limitations where the sodalite production was limited at the elevated firing temperatures required to get high density pellets and the high processing temperatures usually led to chloride volatility and, subsequently, nepheline formation.…”

Section: Introductionmentioning

confidence: 99%

Solution-derived sodalite made with Si- and Ge-ethoxide precursors for immobilizing electrorefiner salt

Riley

Lepry

Crum

2016

Journal of Nuclear Materials

Self Cite

View full text Add to dashboard Cite

Chlorosodalite has the general form of Na8(AlSiO4)6Cl2 and this paper describes experiments conducted to synthesize sodalite with a solution-based approach to immobilize a simulated spent electrorefiner salt solution containing a mixture of alkali, alkaline earth, and lanthanide chlorides. The reactants used were the salt solution, NaAlO2, and either Si(OC2H5)4 or Ge(OC2H5)4. Additionally, seven different glass binders at loadings of 5 mass% were evaluated as sintering aids for consolidating the as-made powders using a cold-press-and-sinter technique. This process of using alkoxide additives for the Group IV component can be used to produce large quantities of sodalite at near-room temperature as compared to a method where colloidal silica was used as the silica source. However, the small particle sizes inhibited densification during heat treatment.

show abstract

Solution‐Derived, Chloride‐Containing Minerals as a Waste Form for Alkali Chlorides

Cited by 25 publications

References 31 publications

Ceramic Solidification of Salt-containing Waste from Pyrochemical Reprocessing of Spent Nuclear Fuel

Ceramic Solidification of Salt-containing Waste from Pyrochemical Reprocessing of Spent Nuclear Fuel

Options for the Separation and Immobilization of Technetium

Solution-derived sodalite made with Si- and Ge-ethoxide precursors for immobilizing electrorefiner salt

Contact Info

Product

Resources

About