Browsing by Author "Simeone, D"

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    Editorial: Ordered and disordered cubic systems: pyrochlore to fluorite, now and the horizon
    (Frontiers Media S.A., 2022-01-12) Thorogood, GJ; Finkeldei, SC; Lang, MK; Simeone, D
    Any internet search for the term pyrochlore, fluorite or the derivation of the two will yield tens of thousands of results. This is clear evidence that the study of these systems, especially since the publication of the landmark review by Subramanian et al. (1983) in 1983 increases with every passing year. The minerals fluorite and pyrochlore can be thought of as two ends of a continuum that encompass other variations such as defect fluorite. Materials with a fluorite structure are used in a wide range of applications, one reason being its ability to incorporate structural disorder. A cubic structure is the simplest in terms of symmetry and thus can accommodate certain amounts of variation in occupancy of atomic positions over a range of different crystallographic sites. It is this versatility that has seen these humble structures applied to all manner of uses ranging from fuel in a nuclear reactor (Simeone et al., 2017), fuel cell anodes (Lang et al., 2009), ion conductors (Wilde and Catlow, 1998), nuclear waste immobilization (Ewing et al., 2004), thermal barrier coatings (Wilde and Catlow, 1998), catalysts (Kim et al., 2020), and superconductors (Yonezawa et al., 2004) to name only a few. Often there is a common thread in these publications which is investigating in one form or another the order or disorder in those systems with one extreme example being high entropy pyrochlores (Oses et al., 2020). It was our goal with this special edition to give an overview of what has traditionally been thought to be disorder in pyrochlore, how it relates to defect fluorite, to highlight the newest discoveries as well as the path forward in this research area. We included the effect of order or disorder induced by external means (irradiation, ball milling, pressure, and temperature), induced internally (changes in chemical composition and stoichiometry) and studies that advance the understanding of disorder occurring in those systems and the effect it has on the structure and properties. These studies were planned to encompass experimental, theoretical (such a density functional theory modelling) or a combination of both studies as is common in the current literature. Copyright © 2022 Thorogood, Finkeldei, Lang and Simeone. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY).
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    Insight into disorder, stress and strain of radiation damaged pyrochlores
    (European Association of Geochemistry and the Geochemical Society (Goldschmidt), 2021-07-07) Finkeldei, SC; Chang, S; Brandt, F; Bosbach, D; Ionescu, M; Avdeev, M; Simeone, D; Thorogood, GJ
    A2B2O7 pyrochlores are considered as potential nuclear waste forms for e.g. plutonium immobilization. Once radionuclides are immobilized within these waste forms, self-irradiation can cause order/disorder transitions of these nuclear waste form candidates. The aim of this study was to detect the early onset of phase transformation in relation to stress and strain of different pyrochlores: titanate based pyrochlores which are prone to amorphization, and zirconate based pyrochlores that are known to undergo a transformation to defect fluorite. Helium ion irradiation experiments of the two pyrochlore types were conducted at 2-6 MeV with a fluence of 1 x 1016 ions/cm2 resulting in approximately 1 dpa to study the onset of disorder in thin samples, to mimic bulk damage. A combined approach of synchrotron X-ray diffraction (XRD), neutron diffraction, and transmission electron microscopy (TEM) as well as electron backscattered diffraction (EBSD) techniques was utilized to understand the structural and microstructural response towards radiation. Irradiation of the Er2Ti2O7 ceramics resulted in a partially fractured sample most likely caused by strain relief. Neutron diffraction data revealed the formation of amorphized regions whereas some crystallinity remained without signs of stress or strain after irradiation. For Nd2Zr2O7, ion irradiation caused the formation of two pyrochlore phases instead of the expected pyrochlore to defect fluorite structural transition. One of the phases appeared to be very similar to the undamaged material while neutron scattering revealed residual stress in the second pyrochlore phase with a significantly reduced lattice parameter compared to the unirradiated Nd2Zr2O7 sample. While we did not observe indications of strain in either of the phases evidence of an increase in disorder of both the cations and anions was observed.
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    Insight Into disorder, stress and strain of radiation damaged pyrochlores: a possible mechanism for the appearance of defect fluorite
    (Frontiers Media S.A., 2021-11-08) Finkeldei, SC; Chang, S; Ionescu, M; Oldfield, DT; Davis, J; Lumpkin, GR; Simeone, D; Avdeev, M; Brandt, F; Bosbach, D; Klinkenberg, M; Thorogood, GJ
    We have examined the irradiation response of a titanate and zirconate pyrochlore—both of which are well studied in the literature individually—in an attempt to define the appearance of defect fluorite in zirconate pyrochlores. To our knowledge this study is unique in that it attempts to discover the mechanism of formation by a comparison of the different systems exposed to the same conditions and then examined via a range of techniques that cover a wide length scale. The conditions of approximately 1 displacement per atom via He2+ ions were used to simulate long term waste storage conditions as outlined by previous results from Ewing in a large enough sample volume to allow for neutron diffraction, as not attempted previously. The titanate sample, used as a baseline comparison since it readily becomes amorphous under these conditions behaved as expected. In contrast, the zirconate sample accumulates tensile stress in the absence of detectable strain. We propose this is analogous to the lanthanide zirconate pyrochlores examined by Simeone et al. where they reported the appearance of defect fluorite diffraction patterns due to a reduction in grain size. Radiation damage and stress results in the grains breaking into even smaller crystallites, thus creating even smaller coherent diffraction domains. An (ErNd)2(ZrTi)2O7 pyrochlore was synthesized to examine which mechanism might dominate, amorphization or stress/strain build up. Although strain was detected in the pristine sample via Synchrotron X-ray diffraction it was not of sufficient quality to perform a full analysis on. Copyright © 2021 Finkeldei, Chang, Ionescu, Oldfield, Davis, Lumpkin, Simeone, Avdeev, Brandt, Bosbach, Klinkenberg and Thorogood.
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    Insight into the order-disorder transition of irradiated pyrochlore solid solutions as potential nuclear waste forms
    (European Association of Geochemistry and the Geochemical Society (Goldschmidt), 2021-07-07) Chang, S; Thorogood, GJ; Avdeev, M; Brandt, F; Bosbach, D; Ionescu, M; Simeone, D; Finkeldei, SC
    Pyrochlores (A2B2O7), a common mineral that can uptake large quantities of actinides, are studied as potential nuclear waste forms to immobilize radionuclides. Many have studied pyrochlore solid solutions where different cations on the A or B site are mixed to imitate waste loading of e.g. Pu within the pyrochlore structure. As a response to irradiation or self-irradiation, zirconate (B=Zr) pyrochlores are known to undergo an order/disorder phase transition into a disordered defect fluorite structure while titanate (B=Ti) pyrochlores become amorphous, however the dominating factor towards phase transition of each is unclear in a solid solution. To gain insight into order-disorder processes, the stress and strain of Nd2Zr2O7 and Er2Ti2O7 endmembers and a (ErNd)2(TiZr)2O7 solid solution were examined. Prior and upon irradiation Nd2Zr2O7 and Er2Ti2O7 both showed no strain. With regards to (ErNd)2(TiZr)2O7, it appears that the synthesis method employed was not sufficient to achieve a 50:50 ratio of A and B cations according to the diffraction results. However, the solid solution contained strain while Nd2Zr2O7 and Er2Ti2O7 was strain free. Further synthesis approaches of (ErNd)2(TiZr)2O7 solid solution members are under way to understand the irradiation response of such mixed A and B site pyrochlores.
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    Intricate disorder in defect fluorite/pyrochlore: a concord of chemistry and crystallography
    (Springer Nature, 2017-06-16) Simeone, D; Thorogood, GJ; Huo, D; Luneville, L; Baldinozzi, G; Petricek, V; Porcher, F; Ribis, J; Mazerolles, L; Largeau, L; Berar, JF; Surble, S
    Intuitively scientists accept that order can emerge from disorder and a significant amount of effort has been devoted over many years to demonstrate this. In metallic alloys and oxides, disorder at the atomic scale is the result of occupation at equivalent atomic positions by different atoms which leads to the material exhibiting a fully random or modulated scattering pattern. This arrangement has a substantial influence on the material’s properties, for example ionic conductivity. However it is generally accepted that oxides, such as defect fluorite as used for nuclear waste immobilization matrices and fuel cells, are the result of disorder at the atomic scale. To investigate how order at the atomic scale induces disorder at a larger scale length, we have applied different techniques to study the atomic composition of a homogeneous La 2 Zr 2 O 7 pyrochlore, a textbook example of such a structure. Here we demonstrate that a pyrochlore, which is considered to be defect fluorite, is the result of intricate disorder due to a random distribution of fully ordered nano-domains. Our investigation provides new insight into the order disorder transformations in complex materials with regards to domain formation, resulting in a concord of chemistry with crystallography illustrating that order can induce disorder. © The Author(s) 2017
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    Radiation-induced micro-structures as ground states of a Swift-Hohenberg energy functional
    (American Institute of Physics (AIP), 2019-02-08) Simeone, D; Thorogood, GJ; Murphy, GL; Forestier, A; Garcia, P; Luneville, L
    We demonstrate that the Swift-Hohenberg functional, which is used to describe patterning observed in out of equilibrium systems such as diblock copolymers, Rayleigh-Benard convection, and thin film magnetic garnets, can be applied to radiation-induced patterns that occur in non-miscible alloys. By comparing ground states obtained from the minimization of this functional and a 2D numerical simulation performed on an irradiated AgCu material, which is the archetype of a non-miscible alloy, we show that the Swift-Hohenberg functional provides all possible patterns generated under irradiation and the solubility limits of radiation-induced precipitates in these patterns. To rationalize the formation of these radiation-induced patterns, we propose a generic “pseudophase diagram” that relies not only on the irradiation flux and temperature but also on the overall composition of the alloy. Tuning this overall composition offers the opportunity to tailor new materials with various micro-structures overcoming the limitation of the equilibrium phase diagram. © 2019 Author(s). Published under license by AIP Publishing.