High-Resolution Solid-State Oxygen-17 NMR of Actinide-Bearing Compounds: An Insight into the 5f Chemistry

Martel, Laura; Magnani, N.; Vigier, Jean-François; Boshoven, Jacobus; Chris, Selfslag; Farnan, Ian; Griveau, Jean‐Christophe; Somers, J.; Fanghänel, Thomas

doi:10.1021/ic5007555

Cited by 39 publications

(84 citation statements)

References 68 publications

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“…4 Nonetheless, the sensitivity of paramagnetic 17 O NMR spectra to distances from, and the electronic and magnetic properties of, the paramagnetic centre has enabled insights in recent years into materials as diverse as metal-organic frameworks, 5 battery materials, 6 mixed ionic-electronic conductors, 7,8 and phases of geological and radiochemical relevance. 9,10 In these studies, computational results from periodic DFT calculations have also played a critical role, aiding in spectral assignment. Nonetheless, the behaviour of paramagnetic Lanthanides can have very large electron magnetic moments due to partial filling of the seven f-orbitals; moreover, the f-orbitals are contracted and hence do not interact strongly with bonded atoms, so that there is minimal crystal field splitting and therefore no driving force to undergo electron pairing and reduce the magnetic moment.…”

Section: Introductionmentioning

confidence: 99%

A 17O paramagnetic NMR study of Sm2O3, Eu2O3, and Sm/Eu-substituted CeO2

Hope

Halat

Lee

et al. 2019

Solid State Nuclear Magnetic Resonance

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Paramagnetic solid-state NMR of lanthanide (Ln) containing materials can be challenging due to the high electron spin states possible for the Ln f electrons, which result in large paramagnetic shifts, and these difficulties are compounded for 17 O due to the low natural abundance and quadrupolar character. In this work, we present examples of 17 O NMR experiments for lanthanide oxides and strategies to overcome these difficulties. In particular, we record and assign the 17 O NMR spectra of monoclinic Sm2O3 and Eu2O3 for the first time, as well as performing density functional theory (DFT) calculations to gain further insight into the spectra. The temperature dependence of the Sm 3+ and Eu 3+ magnetic susceptibilities are investigated by measuring the 17 O shift of the cubic sesquioxides over a wide temperature range, which reveal non-Curie temperature dependence due to the presence of low-lying electronic states. This behaviour is reproduced by calculating the electron spin as a function of temperature, yielding shifts which agree well with the experimental values. Using the understanding of the magnetic behaviour gained from the sesquioxides, we then explore the local oxygen environments in 15 at% Sm-and Eu-substituted CeO2, with the 17 O NMR spectrum exhibiting signals due to environments with zero, one and two nearest neighbour Ln ions, as well as further splitting due to oxygen vacancies. Finally, we extract an activation energy for oxygen vacancy motion in these systems of 0.35 ± 0.02 eV from the Arrhenius temperature dependence of the 17 O T1 relaxation constants, which is found to be independent of the Ln ion within error. The relation of this activation energy to literature values for oxygen diffusion in Ln-substituted CeO2 is discussed to infer mechanistic information which can be applied to further develop these materials as solid-state oxide-ion conductors. Recent efforts by Heinzmann et al. have shown that 17 O NMR (and T1) measurements can be applied to GDC to quantify doping behaviour and to extract activation energy values that can be ascribed to oxideion motion. 41 However, to our knowledge 17 O NMR and/or relaxometry-based techniques have not been used to study conduction in other Ln-substituted CeO2 materials, likely due to the aforementioned difficulties in interpreting NMR spectra of paramagnetic phases. In this work, we apply the lessons learned regarding the magnetic behaviour of Sm 3+ and Eu 3+ as seen in the paramagnetic 17 O NMR of the monoclinic Ln2O3 polymorphs to guide the analysis of variable-temperature 17 O spectra of Sm-and Eu-substituted CeO2.

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Section: Introductionmentioning

confidence: 99%

A 17O paramagnetic NMR study of Sm2O3, Eu2O3, and Sm/Eu-substituted CeO2

Hope

Halat

Lee

et al. 2019

Solid State Nuclear Magnetic Resonance

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“…The NMR shifts of nuclei interacting with paramagnetic d-or f-electron centers have been discussed in detail by Shulman and Jaccarino. 20 Gabuda et al 29 and Martel et al 35 have proposed that the field dependent anisotropic hyperfine shifts in paramagnetic tetravalent actinide systems can be approximated as a dipolar field produced by localized, unpaired electrons at the An 4+ sites…”

Section: Resultsmentioning

confidence: 99%

Probing thePu4+magnetic moment inPuF4withF19

et al. 2016

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The magnetic fields produced by Pu 4+ centers have been measured by 19 F NMR spectroscopy to elucidate the Pu-F electronic interactions in polycrystalline PuF 4. Spectra acquired at applied fields of 2.35 and 7.05 T reveal a linear scaling of the 19 F lineshape. A model is presented that treats the linebroadening and shifts as due to dipolar fields produced by Pu valence electrons in localized non-interacting orbitals. Alternative explanations for the observed lineshape involving covalent Pu-F bonding, superexchange interactions, and electronic configurations with enhanced magnetic moments are considered.

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“…Lattice parameter (Å ) Pu 1Ày Am y O 2 This study Literature y = 0.018 5.3954 (5) 5.396 (1) for y = 0 (Zachariasen, 1949) 5.396 (1) for y = 0 (Drummond & Welch, 1957) 5.396 (1) for y = 0 (Gardner et al, 1965) 5.4026 (6) for y = 0 (Molen & White, 1967) 5.3948 for y = 0 (Nutt & Tokar, 1972) 5.3953 (4) for y = 0 (Noe & Fuger, 1974) 5.3954 (4) for y = 0 (Yamashita et al, 1997) 5.3975 for y = 0 (Haschke et al, 2000) 5.3977 for y = 0 (Martel et al, 2014) 5.400 (1) for y = 0.008 (Belin et al, 2013) y = 0.077 5.3948 (5) 5.397 for y = 0.09 (Miwa et al, 2007) 5.409 (1) for y = 0.1 (Belin et al, 2013) y = 0.21 5.3916 (5) 5.392 (1) (Jankowiak et al, 2009) 5.411 (1) for y = 0.2 (Belin et al, 2013) y = 0.49 5.3859 (5) 5.386 (1) (Jankowiak et al, 2009) 5.383 (1) for y = 0.5 (Otobe et al, 2009) y = 0.80 5.3800 (5) 5.379 (1) (Jankowiak et al, 2009) y = 1.00 5.3755 (5) 5.377 (3) (Zachariasen, 1949) 5.383 (1) (Templeton & Dauben, 1953) 5.377 (Keller, 1967) 5.3772 (4) (Chikalla & Eyring, 1968) 5.3733 (Fahey et al, 1974) 5.3724 (4) (Hurtgen & Fuger, 1977) 5.375 (1) (Prieur et al, 2011) 5.375 (1) (Lebreton et al, 2012) 5.375 (1) (Epifano et al, 2016(Epifano et al, , 2017 to confirm that our samples were stoichiometric, i.e. exhibited an O/M ratio equal to 2.00, at room temperature regardless of the americium content.…”

Section: Tablementioning

confidence: 99%

Lattice thermal expansion of Pu_1−yAm_yO_2−x plutonium–americium mixed oxides

2017

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Plutonium–americium mixed oxides, Pu1−yAmyO2−x, with various Am contents (y = 0.018, 0.077, 0.21, 0.49, 0.80 and 1.00) were studied in situ by high‐temperature X‐ray diffraction. In this study, the lattice thermal expansion of the six compounds subjected to heat treatments up to 1773 K under reconstituted air (N2 + 21% O2 + ∼5 vpm H2O) was investigated. The materials remained monophasic throughout the experiments and, depending upon the americium content, the lattice parameter of the face‐centred cubic phase deviated from linear lattice expansion at elevated temperatures as a result of the progressive reduction of Am4+ to Am3+.

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High-Resolution Solid-State Oxygen-17 NMR of Actinide-Bearing Compounds: An Insight into the 5f Chemistry

Cited by 39 publications

References 68 publications

A 17O paramagnetic NMR study of Sm2O3, Eu2O3, and Sm/Eu-substituted CeO2

A 17O paramagnetic NMR study of Sm2O3, Eu2O3, and Sm/Eu-substituted CeO2

Probing thePu4+magnetic moment inPuF4withF19

Lattice thermal expansion of Pu_1−yAm_yO_2−x plutonium–americium mixed oxides

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High-Resolution Solid-State Oxygen-17 NMR of Actinide-Bearing Compounds: An Insight into the 5f Chemistry

Cited by 39 publications

References 68 publications

A 17O paramagnetic NMR study of Sm2O3, Eu2O3, and Sm/Eu-substituted CeO2

A 17O paramagnetic NMR study of Sm2O3, Eu2O3, and Sm/Eu-substituted CeO2

Probing thePu4+magnetic moment inPuF4withF19

Lattice thermal expansion of Pu1−y Am y O2−x plutonium–americium mixed oxides

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Lattice thermal expansion of Pu_1−yAm_yO_2−x plutonium–americium mixed oxides