Barium zirconate ceramics for melt processing of barium cuprate superconductors

Kirby, Nigel Matthew

January 2003

The widespread use of high temperature superconductors through improved understanding of their underlying physics is in part dependent on the synthesis of large, high quality single crystals for physical research. Crucible corrosion is an important factor hindering the routine synthesis of large, high purity rare-earth barium cuprate superconductor single crystals. Molten BaCuO2-CuO fluxes required for the growth of such crystals are highly corrosive to substrate materials, and corrosion products may lead to chemical contamination of crystals and other practical difficulties. BaZrO3 is known to be inert to BaCuO2-CuO melts, but its use has remained restricted to a very small number of laboratories worldwide because it is very sensitive to the effects of off- stoichiometric or residual secondary phases which degrade its performance. BaZrO3 suitable for sustained melt containment is difficult to produce due to kinetic limitations of phase purity, difficulty in sintering to adequate density, and very narrow stoichiometry tolerances of finished ceramics. The existing literature provided a guide to the production of high quality BaZrO3, but was not sufficiently complete to readily allow production of crucibles suitable for this application. The two basic aims of this project were: To provide a comprehensive and quantitative description of the necessary attributes of crucibles for barium cuprate melt processing and to expand the knowledge of solid-state BaZrO3 processing to encourage its widespread application to crucible manufacture; To explore the application of solution chemical processes whose potential benefits could lead to routine application of BaZrO3 through improved ceramic quality and processing properties. / Based primarily on solid-state processing research, the optimal stoichiometry for corrosion resistant crucibles was observed over the narrow range of 1.003±0.003 Ba : (Zr + Ht) mole ratio. Residual ZrO2 must be strictly avoided even at very low levels because severe localized expansion of Z a grains during reaction with the melt severely reduces corrosion resistance. Although the effect of Ba-rich phases are less severe, their abundance must be suppressed as much as allowed by the production process. Solid-state derived crucibles with a large barium excess were unstable and readily attacked by water. TEM analysis clearly showed residual Zr02 was present as discrete grains and not as grain boundary films, and also the prevalence of intragranular defects in Ba-rich ceramics. Quantitative knowledge of the narrow range of required stoichiometry is critical for developing successful solid-state and solution chemical processes. Reliably achieving the required stoichiometry and phase purity is experimentally challenging and beyond the capability of many processing systems. Systematic investigation revealed sharp changes in physical properties of processed powders across the phase boundary. The resistance of BaZrO3, of the desired stoichiometry to grain growth during powder processing has not previously been reported in the available literature. At the desired stoichiometry for corrosion resistance, powder grain growth resistance combined with very precise control over stoichiometry makes the solid-state process more competitive with solution-based processes than previously acknowledged in the literature. The development of solution processes for BaZr03 precursors is complicated by aqueous chemistry of zirconium compounds. / This project developed the first chemically derived precursor process demonstrated to produce a ceramic of adequate quality for sustained barium cuprate melt containment. The barium acetate / zirconium oxychloride / ammonium oxalate system provided control over stoichiometry without requiring elevated solution temperatures, a large excess of barium reagents, or reagents containing alkalis. Despite showing the capability to supersede the solid-state process, the oxalate process still requires further refinement to more reliably achieve high sintered densities. Although the attributes required for sustained barium cuprate melt containment are now clear, its routine mass production remains reliant on further development of solution chemical techniques or improvements to the kinetics of solid-state processing. This project advanced ceramic design and processing technology in the BaZrO3 system and provided new approaches in meeting the challenging analytical needs of research and process control for high quality production of this compound.

Development of microstructures in YBa←2Cu←3O←7←-←x superconductors

Zhang, Jingli

January 1995

No description available.

530.41

Étude computationnelle des propriétés structurales des matériaux BaMxZr1-xO3 (M=Y, In et Sc ; x=0,125, 0,25 et 0,375) en relation avec leur conductivité protonique / Computational study of structural properties of BaMxZr1-xO3 (M=Y, In and Sc ; x=0.125, 0.25 and 0.375) materials in relation to their proton conductivity

Zeudmi Sahraoui, Djamila

17 December 2012

À l'heure actuelle, le développement dans les piles à combustible gagne un regard considérable pour la cogénération de l'énergie propre. Plus particulièrement, les piles à combustible à conduction protonique dont leurs électrolytes sont des oxydes de type pérovskite. Nous nous sommes intéressés aux électrolytes des piles de type PCFC « Proton Ceramic Fuel Cell » dont la température de fonctionnement est intermédiaire. L'intérêt porté pour l'amélioration de la diffusion du proton au sein de ces matériaux implique une compréhension fondamentale de l'interaction du proton avec son environnement. Cette problématique a conduit à une étude systématique en appliquant l'approche de la théorie de la fonctionnelle de la densité sur les matériaux de BaMxZr1-xO3 (M=Y, In et Sc ; x=12,5, 25 et 37,5%). Dans un premier temps, la validation de la méthode appliquée sur le système idéal de BaZrO3 et BaZr0,625Y0,375O3 a été nécessaire afin de reproduire les propriétés électroniques, structurales et de vibration de phonon en bon accord avec les résultats expérimentaux. Dans un deuxième temps, la variation des propriétés électroniques et structurales en fonction de la nature du dopant accepteur (M=Y, In et Sc), sa répartition dans le réseau, et sa concentration ont été étudiées. Une distorsion locale autour de l'atome dopant dans le réseau a été obtenue. Par conséquent, une baisse de symétrie du réseau a été déterminée. Cette distorsion est remarquée quel que soit la nature du dopant. La différence la plus marquée de l'effet de la nature du dopant est trouvée sur les charges atomiques des ions oxygène selon trois environnement possible : Zr-O(1)-Zr, Zr-O(2)-M et M-O(3)-M. Une diminution de la charge (et donc diminution de la basicité) sur le site O3 est bien remarquée dans BaMxZr1-xO3. On attribue cette diminution de charge à la formation d'une liaison covalente à caractère anti-liant Y-O2 (O3). La liaison est ionique pour Sc-O2(O3) et covalente de faible caractère liant pour In-O2 (O3). Nous avons poursuivi nos investigations sur l'insertion d'hydrogène dans les matériaux étudiés. L'analyse des propriétés électroniques, structurales, des vibrations de phonon et l'énergie d'interaction de l'hydrogène des structures BaMxZr1-xO3H, nous ont permis d'établir une corrélation entre le caractère de la liaison chimique M-O, l'insertion du proton et la force de la liaison O-H. L'insertion de H sur le site O3 dans BaYxZr1-xO3 (x=0,25 et 0,375) n'est pas obtenue, probablement à cause de la faible basicité de l'ion oxygène dans la configuration Y-O3-Y. L'insertion du H sur le site O3 pour les deux configurations In-O-In et Sc-O-Sc est obtenue dans BaInxZr1-xO3 (x=0,25 et 0,375) et BaScxZr1-xO3 (x=0,25 et 0,375) respectivement. La variation de l'énergie d'interaction de l'hydrogène avec son environnement dévoile une stabilisation des défauts protoniques significativement plus importante dans le cas de l'atome dopant accepteur yttrium que dans le cas des dopants In et Sc. L'analyse des fréquences de vibration de valence de la liaison O-H a montrée que cette liaison est plus forte dans BaInxZr1-xO3 et BaScxZr1-xO3 que dans BaYxZr1-xO3. En conclusion, nos résultats démontrent que le matériau BaZrO3 dopé en Y favorise plus la formation des défauts protoniques avec une liaison O-H moins forte que dans les matériaux baryum zirconates dopés en In et Sc. / At the present, the development of fuel cells gains a significant interest for their application in clean energy technologies, more specifically, the proton conducting fuel cells. We are interested in the perovskite oxides electrolytes used in PCFC fuel cell “Proton Ceramic Fuel Cell” which operates at intermediate temperature. The interest for the improvement of proton diffusion in these materials necessitates a fundamental systematic understanding of the proton interaction with its environment. Therefore we applied Density Functional Theory based approach on ideal BaZrO3 and doped barium zirconates BaMxZr1-xO3 (M=Y, Sc and In ; x=12.5, 25 and 37.5%), currently known among the best candidates for PCFC electrolytes. First, the validation of the method applied to the ideal system and BaY0.375Zr0.625O3 was necessary in order to reproduce the electronic, structural and phonon vibration in good agreement with the experimental results. Second, the variation of electronic and structural properties and of the phonon vibration was studied as a function of acceptor dopant nature, positions in the lattice and concentration. A local distortion around the dopant atom in the lattice was obtained. Therefore a reduction of the symmetry system has been determined. This distortion is noticeable regardless of the nature of the dopant. The most striking difference due to the dopant nature is found for the atomic charges on three possible oxygen environments : Zr-O(1)-Zr, Zr-O(2)-M and M-O(3)-M. A decrease in the atomic charge of O3 site (decrease of basicity) is well observed in BaYxZr1-xO3. This decrease in the charge can be attributed to the formation of a covalent anti-binding Y-O2(O3) bond. The binding is ionic for Sc-O2 and slightly covalent with a maximum of 15% covalency for In-O2. Our next investigations were focused on the insertion of hydrogen in the studied materials. The analysis of the computed electronic and structural properties, phonon vibrations and hydrogen interaction energies allowed us to establish a correlation between the nature of the chemical bonding M-O, the insertion energy of the proton and the O-H bond strength. The insertion of hydrogen in O3 site in BaYxZr1-xO3 (x=0.25 and 0.375) is not obtained, probably due to the low basicity of the oxygen ion in the configuration Y-O-Y. The insertion of H at the oxygen site for both In-O3-In and Sc-O3-Sc configurations found to be energetically favored in BaInxZr1-xO3 (x=0.25 and 0.375) and BaScxZr1-xO3 (x=0.25 and 0.375) respectively. The variation of hydrogen interaction energy with its environment reveals a significantly stronger stabilization of proton defects in the case of yttrium acceptor dopant than in the two other barium zirconates doped with In and Sc. The analysis of O-H stretching vibration frequencies has shown that the O-H bond is stronger in BaInxZr1-xO3 and BaScxZr1-xO3 than in BaYxZr1-xO3. In conclusion, our results show that the Y doped barium zirconate material favors the formation of proton defects, with a weaker O-H bond than in In and Sc doped oxides.

Matériaux BaZrO3 dopé

Pcfc

Conductivité protonique

Défauts protoniques

Dopants accepteurs

Doped BaZrO3 materials

Pcfc

Proton conductor

Protonic defect

Density Functional Theory

Acceptor dopants

Structure locale dans un ferroélectrique relaxeur : BaTi(1-x)Zr(x)O3

Laulhé, Claire

26 October 2007

Les ferroélectriques relaxeurs se caractérisent par un large pic de permittivité en fonction de la température, dépendant de la fréquence du champ de mesure. Ce comportement est généralement attribué à la présence de régions polaires de taille nanométrique. L'un des enjeux expérimentaux est la détermination de la nature structurale de ces régions, nécessitant entre autres l'utilisation de sondes de la structure locale. L'objet de ce travail est l'étude de la structure locale dans les pérovskites relaxeurs BaTi1-xZrxO3 (0.25 ≤ x ≤ 0.50), présentant une substitution isovalente Ti4+/Zr4+. Les techniques expérimentales utilisées sont l'absorption des rayons X (EXAFS et XANES) et la détermination de la fonction de distribution de paires par diffusion totale des neutrons. Les déplacements des cations Ti4+ et Zr4+ dans leur cage d'oxygènes ont pu être déterminés. Le principal résultat est que les cations Ti4+ jouent un rôle majeur dans la polarisation locale des relaxeurs BaTi1-xZrxO3. Par ailleurs, il est montré que la déformation des octaèdres ZrO6 dépend directement de la répartition locale des Ti et des Zr dans la solution solide.

Ferroélectriques

ferroélectriques relaxeurs

pérovskite

structure locale

transitions de phase

BaTiO3

BaZrO3

solution solide

absorption des rayons X

EXAFS

XANES

diffusion totale des neutrons

fonction de distribution de paires

Epitaxial Perovskite Superlattices For Voltage Tunable Device Applications

Choudhury, Palash Roy

10 1900

Perovskite based artificial superlattices has recently been extensively investigated due to the immense promise in various device applications. The major applications include non-volatile random access memories, microwave devices, phase shifters voltage tunable capacitor applications etc. In this thesis we have taken up the investigation of two different types of symmetric superlattices, viz. BaZrO3/BaTiO3 and SrTiO3/BaZrO3, with possible applicability to voltage tunable devices. Chapter 1 deals with the introduction to the perovskite based functional oxides. Their various applications and the specific requirements for voltage tunable device applications has also been discussed in detail. The basic properties of BaTiO3 and SrTiO3, which are well documented in the literature, have been reviewed. The fundamental physics of interfacial interactions that influence the properties of superlattices is also discussed using existing models. The reason behind the choice of constructing artificial superlattices of BaZrO3/BaTiO3 and SrTiO3/BaZrO3 and the motivation behind this thesis is outlined. Chapter 2 gives a brief description of the basic characterization techniques that has been employed for studying the thin films. These include pulsed laser deposition of oxide thin films, structural characterization using X-Ray Diffraction and Atomic Force Microscope and electrical characterization of thin film metal-insulator-metal structures. The basic principle behind the techniques has also been included in various sections of this chapter. Chapter 3 introduces the reader to basic properties of the less studied perovskite material BaZrO3, one of the parent components of Ba(Zr,Ti)O3 based ceramics for high frequency applications. BaZrO3 is the common material in both the types of superlattices studied in this thesis. Initially the growth of polycrystalline BaZrO3 on (111)Pt/TiO2/SiO2/Si has been elaborated in this chapter. After characterizing the crystalline quality of the films and optimizing the growth conditions, epitaxial BaZrO3 films has been grown on (001) SrTiO3 substates. Dielectric properties of epitaxial BaZrO3 film have been measured as a function of temperature and frequencies. The electric field tunability of BaZrO3 films has been calculated from capacitance-voltage data for comparison with superlattice structures. Chapter 4 deals with the basic considerations involving growth of artificial superlattices and multilayers using pulsed laser ablation technique. The fundamental differences between formation of multilayers and superlattices have also been discussed, and the basic considerations for optimizing growth parameters are analyzed in this chapter. X-ray θ-2θ and φ-scans have been performed to investigate crystal quality of superlattices. The growth rates calculated from the satellite reflections in X-ray θ-2θ scans indicate fair degree of control over the growth and φ-scans confirms epitaxial cube-on cube growth of both types of superlattices. Atomic Force microscopy has been used to hcaracterize the film quality and surface morphology of superlattice structures and it has been found that the films have a very smooth surface with rms roughness of the order of few nanometres. Chapter5 deals with the detailed electrical characterization of both types of superlattices structures. Dielectric response showed nearly temperature invariance for both types of superlattices. Polarization measurements show that the heterostructures are in paraelectric state. Even for paraelectric/ferroelectric BaZrO3/BaTiO3 superlattices, stress induced stabilization of the paraelectric state is exhibited in low period superlattices. Paraelectric/paraelectric-SrTiO3/BaZrO3 superlattices exhibited a tunability of ~20% at intermediate modulation periods and an extremely stable dissipation factor with respect to temperature which is very attractive for device application point of view. A maximum tunability of ~40% has been observed for lowest period BaZrO3/BaTiO3 superlattice. Relatively high Quality Factors has been observed for both type of superlattices and their dependence on the modulation periods has been analyzed. Dielectric relaxation data showed that Maxwell-Wanger type of behaviour is exhibited but the presence of a conductance component G had to be realized in the equivalent circuit representation, which originates from the observation of a square law dependence of the alternating current on the frequency. Finally DC electrical characteristics were investigated as a function of temperature to determine the type of conduction mechanism that is involoved. The data has been analyzed using existing theories of high field conduction in thin dielectric films and it has been found that at different temperature ranges, the conduction mechanism varied from bulk limited Poole-Frenkel to Space Charge limited conduction. The activation energy calculation indicate that the physical processes responsible for dielectric relaxation and dc conduction are identical.

Epitaxial Perovskite Superlattices

Voltage Tunable Device

Barium Zirconate

Pulsed Laser Deposition

Thin Film Superlattices

Thin Film Deposition

Pulsed Laser Ablation

Strontium Titanate

BaTiO3/BaZrO3 Superlattices

Electronic Engineering

Advanced BaZrO3-BaCeO3 Based Proton Conductors Used for Intermediate Temperature Solid Oxide Fuel Cells (ITSOFCs)

Bu, Junfu

January 2015

In this thesis, the focus is on studying BaZrO3-BaCeO3 based proton conductors due to that they represent very promising proton conductors to be used for Intermediate Temperature Solid Oxide Fuel Cells (ITSOFCs). Here, dense BaZr0.5Ce0.3Y0.2O3-δ (BZCY532) ceramics were selected as the major studied materials. These ceramics were prepared by different sintering methods and doping strategies. Based on achieved results, the thesis work can simply be divided into the following parts: 1) An improved synthesis method, which included a water-based milling procedure followed by a freeze-drying post-processing, was presented. A lowered calcination and sintering temperature for a Hf0.7Y0.3O2-δ (YSH) compound was achieved. The value of the relative density in this work was higher than previously reported data. It is also concluded that this improved method can be used for mass-production of ceramics. 2) As the solid-state reactive sintering (SSRS) represent a cost-effective sintering method, the sintering behaviors of proton conductors BaZrxCe0.8-xLn0.2O3-δ (x = 0.8, 0.5, 0.1; Ln = Y, Sm, Gd, Dy) during the SSRS process were investigated. According to the obtained results, it was found that the sintering temperature will decrease, when the Ce content increases from 0 (BZCLn802) to 0.3 (BZCLn532) and 0.7 (BZCLn172). Moreover, the radii of the dopant ions similar to the radii of Zr4+ or Ce4+ ions show a better sinterability. This means that it is possible to obtain dense ceramics at a lower temperature. Moreover, the conductivities of dense BZCLn532 ceramics were determined. The conductivity data indicate that dense BZCY532 ceramics are good candidates as either oxygen ion conductors or proton conductors used for ITSOFCs. 3) The effect of NiO on the sintering behaviors, morphologies and conductivities of BZCY532 based electrolytes were systematically investigated. According to the achieved results, it can be concluded that the dense BZCY532B ceramics (NiO was added during ball-milling before a powder mixture calcination) show an enhanced oxygen and proton conductivity. Also, that BZCY532A (NiO was added after a powder mixture calcination) and BZCY532N (No NiO was added in the whole preparation procedures) showed lower values. In addition, dense BZCY532B and BZCY532N ceramics showed only small electronic conductivities, when the testing temperature was lower than 800 ℃. However, the BZCY532A ceramics revealed an obvious electronic conduction, when they were tested in the range of 600 ℃ to 800 ℃. Therefore, it is preferable to add the NiO powder during the BZCY532 powder preparation, which can lower the sintering temperature and also increase the conductivity. 4) Dense BZCY532 ceramics were successfully prepared by using the Spark Plasma Sintering (SPS) method at a temperature of 1350 ℃ with a holding time of 5 min. It was found that a lower sintering temperature (&lt; 1400 ℃) and a very fast cooling rate (&gt; 200 ℃/min) are two key parameters to prepare dense BZCY532 ceramics. These results confirm that the SPS technique represents a feasible and cost-effective sintering method to prepare dense Ce-containing BaZrO3-BaCeO3 based proton conductors. 5) Finally, a preliminary study for preparation of Ce0.8Sm0.2O2-δ (SDC) and BZCY532 basedcomposite electrolytes was carried out. The novel SDC-BZCY532 based composite electrolytes were prepared by using the powder mixing and co-sintering method. The sintering behaviors, morphologies and ionic conductivities of the composite electrolytes were investigated. The obtained results show that the composite electrolyte with a composition of 60SDC-40BZCY532 has the highest conductivity. In contrast, the composite electrolyte with a composition of 40SDC-60BZCY532 shows the lowest conductivity. In summary, the results show that BaZrO3-BaCeO3 based proton-conducting ceramic materials represent very promising materials for future ITSOFCs electrolyte applications. / <p>QC 20150423</p>