Defect thermodynamic and transport properties of nanocrystalline Gd-doped ceria

Surblé, Suzy; Baldinozzi, Gianguido; Dollé, Mickaël; Gosset, Dominique; Petot, C.; Petot-Ervas, G.

doi:10.1007/s11581-007-0169-9

Cited by 11 publications

(5 citation statements)

References 6 publications

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“…As indicated in Table I, the early work of Chiang 8 agrees with the expectation that, in contrast to undoped ceria, nanostructuring in the presence of trivalent dopants decreases overall conductivity; even for grain sizes of only 10 nm, distinct bulk and grain boundary responses were detected in the impedance spectra with grain boundaries adding to the overall material resistance. The result is supported by more recent work from Jasinski, 13 Surble et al, 14 Perez-Coll et al, 15 and Ruiz-Trejo et al 16 While the later studies have been directed toward the exploration of H 2 O uptake and proton transport along grain boundaries, the data nevertheless reveal that doped ceria with grain size of ∼100 nm has resistive grain boundaries. The works of Bellino et al 17 and of Anselmi-Tamburini et al 18 stand in stark contrast to these studies.…”

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confidence: 52%

“…The result is supported by more recent work from Jasinski, 13 Surble et al, 14 PerezColl et al, 15 and Ruiz-Trejo et al 16 While the later studies have been directed toward the exploration of H 2 O uptake and proton transport along grain boundaries, the data nevertheless reveal that doped ceria with grain size of ∼100 nm has resistive grain boundaries. The works of Bellino et al 17 and of Anselmi-Tamburini et al 18 stand in stark contrast to these studies.…”

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confidence: 52%

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Ionic and Electronic Conductivity of Nanostructured, Samaria-Doped Ceria

Souza¹,

Chueh

Jung

et al. 2012

J. Electrochem. Soc.

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The ionic and electronic conductivities of samaria doped ceria electrolytes, Ce 0.85 Sm 0.15 O 1.925−δ , with nanometric grain size have been evaluated. Nanostructured bulk specimens were obtained using a combination of high specific-surface-area starting materials and suitable sintering profiles under conventional, pressureless conditions. Bulk specimens with relatively high density (≥92% of theoretical density) and low medium grain size (as small as 33 nm) were achieved. Electrical A.C. impedance spectra were recorded over wide temperature (150 to 650 • C) and oxygen partial pressure ranges (0.21 to 10 −31 atm). Under all measurement conditions the total conductivity decreased monotonically with decreasing grain size. In both the electrolytic and mixed conducting regimes this behavior is attributed to the high number density of high resistance grain boundaries. The results suggest a possible variation in effective grain boundary width with grain size, as well as a possible variation in specific grain boundary resistance with decreasing oxygen partial pressure. No evidence appears for either enhanced reducibility or enhanced electronic conductivity upon nanostructuring. The transport and redox properties of ceria have been studied extensively due to the suitability of this material to a wide range of applications including fuel cells (as both electrolyte 1, 2 and anode component [2][3][4][5] ) and catalytic convertors. 6 In recent years there have been observations of 'non-trivial' size effects in ceria in which nanostructuring results in dramatically enhanced conductivity, particularly for grain sizes of <30 nm.7 Concomitant with this change in transport properties is a dramatic increase in reducibility, manifest as a decrease in the standard enthalpy of the reduction reaction. 8 Although the details of the observations differ between authors, the grain boundary behavior of undoped ceria free of intergranular impurity phases is relatively well-explained in terms of a space-charge model. 7,9 In brief, due to inherent differences in the chemical bonding environment at grain boundaries and in the bulk, the grain boundary interface or core displays a charge imbalance between anionic and cationic species leading to an interfacial space-charge potential, φ 0 . This potential, in turn, causes a redistribution of mobile species in the near vicinity of the core, i.e., the space charge region. Inferred values of φ 0 in ceria are ∼0.3 to 0.7 V, and, being positive in sign, imply that vacancies are depleted, whereas electron concentrations, resulting from the Ce 4+ /Ce 3+ equilibrium, are enhanced in the space charge region. The width of the space-charge zone (the effective grain boundary thickness) typically falls between 1.2 and 6 nm. For microcrystalline materials, the consequence is that the grain boundaries serve to block the motion of the predominately mobile oxygen vacancies as they traverse the depletion region and migrate from one grain to the next. For nanocrystalline materials, because the volume fraction of gr...

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confidence: 52%

supporting

confidence: 52%

Ionic and Electronic Conductivity of Nanostructured, Samaria-Doped Ceria

Souza¹,

Chueh

Jung

et al. 2012

J. Electrochem. Soc.

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“…22 There are several synthesis methods, including conventional ceramic (solid-state) and soft-chemical methods such as glycine-nitrate, 27 coprecipitation, 28 and polymerization, 29 that are employed to prepare doped ceria electrolytes. These preparation methods play a significant role in determining the microstructure and particle size distributions, which influence the electrical conductivity, [30][31][32][33] and particlesize-dependent conductivity was explained using the space charge model. 34,35 Recently, we have re-examined the chemical stability of Y-doped BaCeO 3 in CO 2 at a temperature range of 600-1000 °C.…”

Section: Introductionmentioning

confidence: 99%

Facile Conversion of Layered Ruddlesden−Popper-Related Structure Y₂O₃-Doped Sr₂CeO₄ into Fast Oxide Ion-Conducting Fluorite-Type Y₂O₃-Doped CeO₂

2008

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The present work shows a new solid- and gas-phase reaction technique for the preparation of a fast oxide-ion-conducting Y(2)O(3)-doped Ce(1-x)Y(x)O(2-delta) (x = 0.1, 0.2) (YCO), which involves the reaction of layered (Ruddlesden-Popper K(2)NiF(4)-type) structure Y(2)O(3)-doped Sr(2)CeO(4) (YSCO) with CO(2) at an elevated temperature and subsequent acid-washing. A powder X-ray diffraction study revealed the formation of a single-phase cubic fluorite-type YCO for the CO(2)-reacted and subsequent acid-washed product. Energy dispersive X-ray analysis showed the absence of Sr in the CO(2)-treated and subsequent acid-washed product, confirming the transformation of layered YSCO into YCO. The cubic lattice constant was found to decrease with increasing Y content in YCO, which is consistent with the other YCO samples reported in the literature. The scanning electron microscopy study showed smaller-sized particles for the product obtained after CO(2)- and acid-washed YCO samples, while the high-temperature sintered YCO and the precursor YSCO exhibit larger-sized particles. The bulk ionic conductivity of the present CO(2)-capture-method-prepared YCO exhibits about one and half orders of magnitude higher electrical conductivity than that of the undoped CeO(2) and was found to be comparable to those of ceramic- and wet-chemical-method synthesized rare-earth-doped CeO(2).

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“…Nonetheless, it is also important to mention here that the electrical conductivity of materials significantly changes with crystalline sizes. For example, Surble et al [52] showed that the ionic conductivity of Gd-doped CeO 2 increases as the grain size decreases and the ionic conductivity goes through a maximum at about 300-500 nm. In a recent work, Tschope and co-worker showed that about two orders of magnitude lower electrical conductivity compared to microcrystalline material was observed [53].…”

Section: Resultsmentioning

confidence: 99%

Studies on chemical stability in CO2 and H2O and electrical conductivity of perovskite-type Ba3In2Zr1−x Ce x O8 (x = 0, 0.5, 1)

El-Masri

Thangadurai

2010

Ionics

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Defect thermodynamic and transport properties of nanocrystalline Gd-doped ceria

Cited by 11 publications

References 6 publications

Ionic and Electronic Conductivity of Nanostructured, Samaria-Doped Ceria

Ionic and Electronic Conductivity of Nanostructured, Samaria-Doped Ceria

Facile Conversion of Layered Ruddlesden−Popper-Related Structure Y₂O₃-Doped Sr₂CeO₄ into Fast Oxide Ion-Conducting Fluorite-Type Y₂O₃-Doped CeO₂

Studies on chemical stability in CO2 and H2O and electrical conductivity of perovskite-type Ba3In2Zr1−x Ce x O8 (x = 0, 0.5, 1)

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Defect thermodynamic and transport properties of nanocrystalline Gd-doped ceria

Cited by 11 publications

References 6 publications

Ionic and Electronic Conductivity of Nanostructured, Samaria-Doped Ceria

Ionic and Electronic Conductivity of Nanostructured, Samaria-Doped Ceria

Facile Conversion of Layered Ruddlesden−Popper-Related Structure Y2O3-Doped Sr2CeO4 into Fast Oxide Ion-Conducting Fluorite-Type Y2O3-Doped CeO2

Studies on chemical stability in CO2 and H2O and electrical conductivity of perovskite-type Ba3In2Zr1−x Ce x O8 (x = 0, 0.5, 1)

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Facile Conversion of Layered Ruddlesden−Popper-Related Structure Y₂O₃-Doped Sr₂CeO₄ into Fast Oxide Ion-Conducting Fluorite-Type Y₂O₃-Doped CeO₂