Single phase melt processed powellite (Ba,Ca)MoO4 for the immobilization of Mo-rich nuclear waste

Brinkman, Kyle S.; Fox, Kevin M.; Marra, James C.; Reppert, Jason; Crum, Jarrod V.; Tang, Ming

doi:10.1016/j.jallcom.2012.09.049

Cited by 43 publications

(25 citation statements)

References 38 publications

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“…As previously mentioned, the fabrication process causes the cell parameters to be higher than single crystals, which irradiation aids in remediating. CaMoO 4 as a single crystal has been previously observed stable against amorphization following Ar-irradiation, which created 5 dpa of structural modifications [48] and low energy electron irradiation produced through in-situ TEM [70]. This study proves that CaMoO 4 is also stable with minimal alteration in a calcium borosilicate for up to 1.34 GGy of β-irradiation, though crystals may migrate through the surrounding amorphous network.…”

Section: Radiation Effectssupporting

confidence: 56%

Impacts of composition and beta irradiation on phase separation in multiphase amorphous calcium borosilicates

Patel

Boizot

Facq

et al. 2017

Journal of Non-Crystalline Solids

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A B S T R A C TBorosilicate glasses for nuclear waste applications are limited in waste loading by the precipitation of watersoluble molybdates. In order to increase storage efficiency, new compositions are sought out that trap molybdenum in a water-durable CaMoO 4 crystalline phase. Factors affecting CaMoO 4 combination and glass-inglass phase separation in calcium borosilicate systems as a function of changing [MoO 3 ] and [B 2 O 3 ] are examined in this study in order to understand how competition for charge balancers affects phase separation. It further examines the influence of radiation damage on structural modifications using 0.77 to 1.34 GGy of 2.5 MeV electron radiation that replicates inelastic collisions predicted to occur over long-term storage. The resulting microstructure of separated phases and the defect structure were analyzed using electron microscopy, XRD, Raman and EPR spectroscopy prior to and post irradiation. Synthesized calcium borosilicates are observed to form an unusual heterogeneous microstructure composed of three embedded amorphous phases with a solubility limit~2.5 mol% MoO 3. Increasing [B 2 O 3 ] increased the areas of immiscibility and order of (MoO 4 ) 2 − anions, while increasing [MoO 3 ] increased both the phase separation and crystallization temperature resulting in phases closer to metastable equilibrium, and initiated clustered crystallization for [MoO 3 ] > 2.5 mol%. β-irradiation was found to have favorable properties in amorphous systems by creating structural disorder and defect assisted ion migration that thus prevented crystallization. It also increased reticulation in the borosilicate network through 6-membered boroxyl ring and Si ring cleavage to form smaller rings and isolated units. This occurred alongside an increased reduction of Mo 6 + with dose that can be correlated to molybdenum solubility.In compositions with existing CaMoO 4 crystallites, radiation caused a scattering effect, though the crystal content remained unchanged. Therefore β-irradiation can preferentially prevent crystallization in calcium borosilicates for [MoO 3 ] < 2.5 mol%, but has a smaller impact on systems with existing CaMoO 4 crystallites.

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Section: Radiation Effectssupporting

confidence: 56%

Impacts of composition and beta irradiation on phase separation in multiphase amorphous calcium borosilicates

Patel

Boizot

Facq

et al. 2017

Journal of Non-Crystalline Solids

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“…z(αn) = ϕT 2 (non-isothermal test methods) (8) and ϕ is the normalized specific heat flow per sample mass [32]. The maxima of the z(an) function vs (an) was found to be within the range predicted using the JMA model, shown in…”

Section: Jmak Crystallization Modelmentioning

confidence: 84%

“…Peterson measured quench rates from the melt to the molten tin to be ~65°C/s and from the molten tin to the water bath at room temperature to be ~30°C/s. [23,[27][28][29][30][31][32]. The Johnson-Mehl-Avrami-Kolmogorov (JMAK) model can be used to characterize the time and temperature dependence of transformation processes, commonly but not limited to characterizing the time and temperature dependence on crystallization.…”

Section: Glass-crystal Transformations Experimentalmentioning

confidence: 99%

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Phase separation and crystallization of complex borosilicate melts for glass-ceramic waste forms

Brow

2019

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Roberts received his Masters' Degree in MSE in December 2018, and this report is based on his thesis for that degree, "Microstructural Development and Its Effect on Aqueous Corrosion of a Borosilicate Glass Ceramic for Waste Vitrification." Paul Porter is a candidate for a PhD in MSE, expected in 2020. His contributions to this study are included in this report. Both students, as well as a number of undergraduate assistants, were supervised by Prof. Richard K. Brow. The report is divided into four sections. The first provides background information about issues associated with waste vitrification, and the development of the borosilicate glass-ceramic materials. The second section describes the effects of thermal history on the phase transformations that occur in the borosilicate glass-ceramic and includes the results of both isothermal and continuous-cooling experiments. The third section describes the effects of thermal history on the chemical durability of the borosilicate glass-ceramics, and includes the results of product consitancy tests performed at Missouri S&T and at Savannah River National Lab. Sections 2 and 3 are written in the form of journal articles. The fourth section is an appendix that includes a description of the hot thermocouple test assembly, as well as data sets used in the first two sections.

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“…For instance, Smith et al multiple other phases such as intermetallic alloy particles, grains of calcium aluminum titanate, and titanium aluminate [76]. Formulations containing Mo waste elements often form well-known alkali molybdates such as Cs 2 MoO 4 with poor aqueous durability [77]. In current SYNROC formulations targeting waste streams from potential commercial nuclear fuel recycling in the United States, the Cs containing hollandite and pyrochlore phase containing the most prevalent lanthanide Nd as Nd 2 Ti 2 O 7 constitute a majority of the phase assemblage (combined $80%), therefore understanding interfacial interactions are of prime interest.…”

Section: Model Single Phase Materials: Interfacial Characteristicsmentioning

confidence: 99%

An Interdisciplinary View of Interfaces: Perspectives Regarding Emergent Phase Formation

Brinkman

2017

Journal of Electrochemical Energy Conversion and Storage

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A perspective on emergent phase formation is presented using an interdisciplinary approach gained by working at the "interface" between diverse application areas, including solid oxide fuel cells (SOFCs) and ionic membrane systems, solid state lithium batteries, and ceramics for nuclear waste immobilization. The grain boundary interfacial characteristics of model single-phase materials in these application areas, including (i) CeO 2 , (ii) Li 7 La 3 Zr 2 O 12 (LLZO), and (iii) hollandite of the form Ba x Cs y Ga 2xþy Ti 8-2x-y O 16 , as well as the potential for emergent phase formation in composite systems, are discussed. The potential physical properties resulting from emergent phase structure and distribution are discussed, including an overview of existing three-dimensional (3D) imaging techniques recently used for characterization. Finally, an approach for thermodynamic characterization of emergent phases based on melt solution calorimetry is outlined, which may be used to predict the energy landscape including phase formation and stability of complex multiphase systems.

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Single phase melt processed powellite (Ba,Ca)MoO4 for the immobilization of Mo-rich nuclear waste

Cited by 43 publications

References 38 publications

Impacts of composition and beta irradiation on phase separation in multiphase amorphous calcium borosilicates

Impacts of composition and beta irradiation on phase separation in multiphase amorphous calcium borosilicates

Phase separation and crystallization of complex borosilicate melts for glass-ceramic waste forms

An Interdisciplinary View of Interfaces: Perspectives Regarding Emergent Phase Formation

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