Plutonium and Americium Aluminate Perovskites

Vigier, Jean-François; Popa, Karin; Martel, Laura; Manara, D.; Blanco, Oliver Dieste; Freis, Daniel; Konings, R.J.M.

doi:10.1021/acs.inorgchem.9b00679

Cited by 10 publications

(5 citation statements)

References 46 publications

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“…The requirements for a stable solid form are very diverse, ranging from storage on earth and operation in space to safe performance in case of accidents and post-accident scenarios. Our group studied several ceramic forms containing significant specific Am amounts, − the present study being in line with the past efforts.…”

Section: Introductionsupporting

confidence: 68%

“…Moreover, 237 Np (the decay product of 241 Am) tends to segregate as a fluorite fcc secondary phase, creating interfaces and inducing stress in the material. Comparing the existing data on Am-containing ceramics with fluorite, pyrochlore, zircon, monazite, and perovskite structures, the (Am,U)O 2 , fluorite solid solution seems currently to be the most suitable form for space applications.…”

Section: Discussionmentioning

confidence: 99%

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Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO₃ and AmVO₄

et al. 2023

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In search for chemically stable americium compounds with high power densities for radioisotope sources for space applications, AmVO3 and AmVO4 were prepared by a solid-state reaction. We present here their crystal structure at room temperature solved by powder X-ray diffraction combined with Rietveld refinement. Their thermal and self-irradiation stabilities have been studied. The oxidation states of americium were confirmed by the Am M5 edge high-resolution X-ray absorption near-edge structure (HR-XANES) technique. Such ceramics are investigated as potential power sources for space applications like radioisotope thermoelectric generators, and they have to endure extreme conditions including vacuum, high or low temperatures, and internal irradiation. Thus, their stability under self-irradiation and heat treatment in inert and oxidizing atmospheres was tested and discussed relative to other compounds with a high content of americium.

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Section: Introductionsupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO₃ and AmVO₄

et al. 2023

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“…As expected in the case of radiation damage induced defects, signal broadening takes place, and additionally the overlapping of all the peaks. 7,43 Due to these spectral changes, it was not possible to obtain a quantitative spectrum and differentiate neatly the crystalline from the amorphous phase. Nonetheless, we noticed that the feature previously attributed to peak 1 (mostly P(OAm) 7 species) was still present with a 31 P NMR shift almost similar to the fresh sample (300 ± 5 ppm vs. 282 ppm) while its line broadening was increasing over time (Figure 5d).…”

Section: Inorganic Chemistrymentioning

confidence: 99%

“…This is the reason why we started to look for alternative stable forms of americium compounds with high americium density as potential space power source materials. Thus, we have focused our effort on the synthesis and characterization of Am-containing compounds with light elements, such as AmAlO 3 7 (76% Am) and AmPO 4 (72% Am). Actinide phosphates are well-known for their stability, being proposed as ceramic nuclear waste forms.…”

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confidence: 99%

Synthesis, Characterization, and Stability of Americium Phosphate, AmPO₄

et al. 2020

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AmPO4 was prepared by a solid-state reaction method, and its crystal structure at room temperature was solved by powder X-ray diffraction combined with Rietveld refinement. The purity of the monazite-like phase was confirmed by spectroscopic (high-resolution solid-state 31P NMR and Raman) and microscopic (SEM-EDX and TEM) techniques. The thermal and self-irradiation stability have been studied. The compound is stable under argon and air atmosphere at least up to 1773 K. It remains crystalline under self-irradiation for circa two months, with a crystallographic volume swelling of ∼1.5%, and then is amorphizing over a year. However, microcrystals are present in the amorphous material even after a two year period of time. All these characteristics are discussed in relation to the potential application of AmPO4 as a stable form of Am in radioisotope power sources for space exploration and of behavior of the monazites under irradiation.

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“…238 Pu and 241 Am) and the associated disintegrations are known to generate a broadening in the XRD peaks due to the induced structural disorder (Clinard et al, 1982;Weber, 1983;Horlait et al, 2013). In some materials, the structural damage generated by decay can lead to a complete amorphization of the material (Walter et al, 2007;Vigier et al, 2019). Furthermore, the self-irradiation generally induces a significant lattice swelling over time (Turcotte, 1976;Weber, 1984;Baclet et al, 2007;Thiebaut et al, 2007;Ravat et al, 2007;Nishi et al, 2013;Lebreton et al, 2014, (Baena et al, 2015) 5.47127 ( 8) (Leinders et al, 2015) 5.434 (1) (Chollet et al, 2014(Chollet et al, , 2012 5.39819 (1) (Belin et al, 2004) 5.3755 ( 5) (Vauchy et al, 2017) 5.593 (3) (Horlait et al, 2012) 5.4702 (4) (Yamashita et al, 1997) 5.4338 (3) (Yamashita et al, 1997) 5.3954 (4) (Yamashita et al, 1997) 5.375 (1) (Epifano et al, 2017(Epifano et al, , 2016 5.5974 (6) (Yamashita et al, 1997) 5.470 (Markin & Street, 1967) 5.4328 (2) (Fahey et al, 1974) 5.3953 (4) (Noe & Fuger, 1974) 5.3733 (Fahey et al, 1974) 5.5972 (5) (Zachariasen, 1948) 5.4704 (1) (Baldock et al, 1966) 5.434 (Sudakov et al, 1973) 5.3960 (3) (Ellinger, 1961) 5.377 (3) (Zachariasen, 1949) Figure 12 Experimental lattice parameters of the fluor...…”

Section: Figurementioning

confidence: 99%

New sample stage for characterizing radioactive materials by X-ray powder diffraction: application on five actinide dioxides ThO₂, UO₂, NpO₂, PuO₂ and AmO₂

et al. 2021

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A new sample stage for characterizing radioactive materials by X-ray powder diffraction was developed at the ATALANTE facility (CEA Marcoule, France) using a conventional (non-nuclearized) Bruker D8 goniometer mounted in Bragg–Brentano geometry. The setup consists of a removable, fully hermetic sample stage, with a 200 µm-thick beryllium window, that can be plugged onto a glove-box, allowing the sample to be introduced in an hermetic medium that also encapsulates the glove-box atmosphere throughout the analysis process. The whole setup is thus hermetically unplugged from the glove-box and positioned on the centre of the goniometer. No preliminary decontamination and/or decontainment of the sample is necessary. The device was developed to avoid an expensive and time-consuming nuclearization of the diffractometer while also keeping it easily accessible for maintenance. Ultimately, keeping the diffractometer out of a glove-box also limits the volume of the final nuclear wastes, and thus the removable sample stage is the only `active' part. X-ray diffraction results of two NIST standards LaB6 and α-Al2O3 as well as five actinide dioxides ThO2, UO2, NpO2, PuO2 and AmO2 are presented to show the efficiency of the setup.

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Plutonium and Americium Aluminate Perovskites

Cited by 10 publications

References 46 publications

Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO₃ and AmVO₄

Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO₃ and AmVO₄

Synthesis, Characterization, and Stability of Americium Phosphate, AmPO₄

New sample stage for characterizing radioactive materials by X-ray powder diffraction: application on five actinide dioxides ThO₂, UO₂, NpO₂, PuO₂ and AmO₂

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Plutonium and Americium Aluminate Perovskites

Cited by 10 publications

References 46 publications

Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO3 and AmVO4

Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO3 and AmVO4

Synthesis, Characterization, and Stability of Americium Phosphate, AmPO4

New sample stage for characterizing radioactive materials by X-ray powder diffraction: application on five actinide dioxides ThO2, UO2, NpO2, PuO2 and AmO2

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Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO₃ and AmVO₄

Synthesis, Characterization, and Stability of Two Americium Vanadates, AmVO₃ and AmVO₄

Synthesis, Characterization, and Stability of Americium Phosphate, AmPO₄

New sample stage for characterizing radioactive materials by X-ray powder diffraction: application on five actinide dioxides ThO₂, UO₂, NpO₂, PuO₂ and AmO₂