16 research outputs found

    Porous Talcum-Based Steatite Ceramics Fabricated by the Admixture of Organic Particles: Experimental Characterization and Effective Medium/Field Modeling of Thermo-Mechanical Properties

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    In this paper, an experimental campaign, as regards the thermo-mechanical properties (heat capacity, thermal conductivity, Young’s modulus, and tensile (bending) strength) of talcum-based steatite ceramics with artificially introduced porosity, is presented. The latter has been created by adding various amounts of an organic pore-forming agent, almond shell granulate, prior to compaction and sintering of the green bodies. The so-obtained porosity-dependent material parameters have been represented by homogenization schemes from effective medium/effective field theory. As regards the latter, thermal conductivity and elastic properties are well described by the self-consistent estimate, with effective material properties scaling in a linear manner with porosity, with the latter in the range of 1.5 vol-%, representing the intrinsic porosity of the ceramic material, to 30 vol-% in this study. On the other hand, strength properties are, due to the localization of the failure mechanism in the quasi-brittle material, characterized by a higher-order power-law dependency on porosity

    Superstructure of mullite-type KAl 9 O 14

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    Large whiskers of a new KAl9O14 polymorph with mullite-type structure were synthesized. The chemical composition of the crystals was confirmed by energy-dispersive X-ray spectroscopy, and the structure was determined using single-crystal X-ray diffraction. Nanosized twin domains and one-dimensional diffuse scattering were observed utilizing transmission electron microscopy. The compound crystallizes in space group P21/n (a = 8.1880(8), b = 7.6760(7), c = 8.7944(9) Å, β = 110.570(8), V = 517.50(9) Å3, Z = 2). Crystals of KAl 9O14 exhibit a mullite-type structure with linear edge-sharing AlO6 octahedral chains connected with groups of two AlO4 tetrahedra and one AlO5 trigonal bipyramid. Additionally, disproportionation of KAl9O14 into K β-alumina and corundum was observed using in situ high-temperature optical microscopy and Raman spectroscopy

    Structural, Spectroscopic, and Computational Studies on Tl<sub>4</sub>Si<sub>5</sub>O<sub>12</sub>: A Microporous Thallium Silicate

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    Single crystals of the previously unknown thallium silicate Tl<sub>4</sub>Si<sub>5</sub>O<sub>12</sub> have been prepared from hydrothermal crystallization of a glassy starting material at 500 °C and 1kbar. Structure analysis resulted in the following basic crystallographic data: monoclinic symmetry, space group <i>C</i>2/<i>c</i>, <i>a</i> = 9.2059(5) Å, <i>b</i> = 11.5796(6) Å, <i>c</i> = 13.0963(7) Å, β = 94.534(5)°. From a structural point of view the compound can be classified as an interrupted framework silicate with Q<sup>3</sup>- and Q<sup>4</sup>-units in the ratio 2:1. Within the framework 4-, 6-, and 12-membered rings can be distinguished. The framework density of 14.4 T-atoms/1000 Å<sup>3</sup> is comparable with the values observed in zeolitic materials like Linde type A, for example. The thallium cations show a pronounced one-sided coordination each occupying the apex of a distorted trigonal TlO<sub>3</sub> pyramid. Obviously, this reflects the presence of a stereochemically active 6s<sup>2</sup> lone pair electron. The porous structure contains channels running along [110] and [−1 1 0], respectively, where the Tl<sup>+</sup> cations are located for charge compensation. Structural investigations have been completed by Raman spectroscopy. The interpretation of the spectroscopic data and the allocation of the bands to certain vibrational species have been aided by DFT calculations, which were also employed to study the electronic structure of the compound

    Surface Reactivity of YSZ, Y<sub>2</sub>O<sub>3</sub>, and ZrO<sub>2</sub> toward CO, CO<sub>2</sub>, and CH<sub>4</sub>: A Comparative Discussion

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    The C1-surface chemistry of catalytically and technologically relevant oxides (YSZ, ZrO<sub>2</sub>, and Y<sub>2</sub>O<sub>3</sub>) toward CH<sub>4</sub>, CO, and CO<sub>2</sub> was comparatively studied by electrochemical impedance (EIS) and spectroscopic (FT-IR) methods. Highly correlated <i>in situ</i> measurements yield a consistent picture with respect to qualitative and quantitative surface modifications as a function of temperature and gas phase composition. This includes not only a detailed study of carbon deposition in methane and adsorption of CO and CO<sub>2</sub> but also proof of the strong influence of surface chemistry. On all studied oxides, carbon deposited during methane treatment grows dynamically forming interconnected islands and eventually a continuous conducting carbon layer at <i>T</i> ≥ 1073 K. Before methane dissociation via gas phase radical reactions/H-abstraction and carbon growth, a complex redox interplay of total oxidation as well as formate and carbonate formation leads to associated surface and grain conductivity changes. For CO adsorption, these measurements yield data on the time and temperature dependence of the adsorbate- and carburization-induced conductivity processes. In that respect, an equivalent circuit model in dry CO allows to disentangle the different contributions of grain interiors, grain boundaries, and electrode contributions. For YSZ, temperature regions with different charge carrier activation energies could be identified, perfectly corresponding to significant changes in surface chemistry. Hydroxyl groups, carbonates, or formates strongly influence the impedance properties, suggesting that the conductivity properties of YSZ, e.g., in a realistic reforming gas mixture, cannot be reduced to exclusive bulk ion conduction. Because of the different degree of hydroxylation and the different ability to chemisorb CO and CO<sub>2</sub>, the influence of the surface chemistry on the electrochemical properties is varying strongly: in contrast to ZrO<sub>2</sub>, the impact of the studied C1-gases on YSZ and Y<sub>2</sub>O<sub>3</sub> is substantial. This also includes the reoxidation/reactivation behavior of the surfaces

    Nanoindentation, High-Temperature Behavior, and Crystallographic/Spectroscopic Characterization of the High-Refractive-Index Materials TiTa<sub>2</sub>O<sub>7</sub> and TiNb<sub>2</sub>O<sub>7</sub>

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    Colorless single crystals, as well as polycrystalline samples of TiTa<sub>2</sub>O<sub>7</sub> and TiNb<sub>2</sub>O<sub>7</sub>, were grown directly from the melt and prepared by solid-state reactions, respectively, at various temperatures between 1598 K and 1983 K. The chemical composition of the crystals was confirmed by wavelength-dispersive X-ray spectroscopy, and the crystal structures were determined using single-crystal X-ray diffraction. Structural investigations of the isostructural compounds resulted in the following basic crystallographic data: monoclinic symmetry, space group <i>I</i>2<i>/m</i> (No. 12), <i>a</i> = 17.6624(12) Å, <i>b</i> = 3.8012(3) Å, <i>c</i> = 11.8290(9) Å, β = 95.135(7)°, <i>V</i> = 790.99(10) Å<sup>3</sup> for TiTa<sub>2</sub>O<sub>7</sub> and <i>a</i> = 17.6719(13) Å, <i>b</i> = 3.8006(2) Å, <i>c</i> = 11.8924(9) Å, β = 95.295(7)°, <i>V</i> = 795.33(10) Å<sup>3</sup>, respectively, for TiNb<sub>2</sub>O<sub>7</sub>, <i>Z</i> = 6. Rietveld refinement analyses of the powder X-ray diffraction patterns and Raman spectroscopy were carried out to complement the structural investigations. In addition, <i>in situ</i> high-temperature powder X-ray diffraction experiments over the temperature range of 323–1323 K enabled the study of the thermal expansion tensors of TiTa<sub>2</sub>O<sub>7</sub> and TiNb<sub>2</sub>O<sub>7</sub>. To determine the hardness (<i>H</i>), and elastic moduli (<i>E</i>) of the chemical compounds, nanoindentation experiments have been performed with a Berkovich diamond indenter tip. Analyses of the load–displacement curves resulted in a hardness of <i>H</i> = 9.0 ± 0.5 GPa and a reduced elastic modulus of <i>E</i><sub>r</sub> = 170 ± 7 GPa for TiTa<sub>2</sub>O<sub>7</sub>. TiNb<sub>2</sub>O<sub>7</sub> showed a slightly lower hardness of <i>H</i> = 8.7 ± 0.3 GPa and a reduced elastic modulus of <i>E</i><sub>r</sub> = 159 ± 4 GPa. Spectroscopic ellipsometry of the polished specimens was employed for the determination of the optical constants <i>n</i> and <i>k</i>. TiNb<sub>2</sub>O<sub>7</sub> as well as TiTa<sub>2</sub>O<sub>7</sub> exhibit a very high average refractive index of <i>n</i><sub>D</sub> = 2.37 and <i>n</i><sub>D</sub> = 2.29, respectively, at λ = 589 nm, similar to that of diamond (<i>n</i><sub>D</sub> = 2.42)

    Mechanical Properties, Quantum Mechanical Calculations, and Crystallographic/Spectroscopic Characterization of GaNbO<sub>4</sub>, Ga(Ta,Nb)O<sub>4</sub>, and GaTaO<sub>4</sub>

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    Single crystals as well as polycrystalline samples of GaNbO<sub>4</sub>, Ga­(Ta,Nb)­O<sub>4</sub>, and GaTaO<sub>4</sub> were grown from the melt and by solid-state reactions, respectively, at various temperatures between 1698 and 1983 K. The chemical composition of the crystals was confirmed by wavelength-dispersive electron microprobe analysis, and the crystal structures were determined by single-crystal X-ray diffraction. In addition, a high-P–T synthesis of GaNbO<sub>4</sub> was performed at a pressure of 2 GPa and a temperature of 1273 K. Raman spectroscopy of all compounds as well as Rietveld refinement analysis of the powder X-ray diffraction pattern of GaNbO<sub>4</sub> were carried out to complement the structural investigations. Density functional theory (DFT) calculations enabled the assignment of the Raman bands to specific vibrational modes within the structure of GaNbO<sub>4</sub>. To determine the hardness (<i>H</i>) and elastic moduli (<i>E</i>) of the compounds, nanoindentation experiments have been performed with a Berkovich diamond indenter tip. Analyses of the load–displacement curves resulted in a high hardness of <i>H</i> = 11.9 ± 0.6 GPa and a reduced elastic modulus of <i>E</i><sub>r</sub> = 202 ± 9 GPa for GaTaO<sub>4</sub>. GaNbO<sub>4</sub> showed a lower hardness of <i>H</i> = 9.6 ± 0.5 GPa and a reduced elastic modulus of <i>E</i><sub>r</sub> = 168 ± 5 GPa. Spectroscopic ellipsometry of the polished GaTa<sub>0.5</sub>Nb<sub>0.5</sub>O<sub>4</sub> ceramic sample was employed for the determination of the optical constants <i>n</i> and <i>k</i>. GaTa<sub>0.5</sub>Nb<sub>0.5</sub>O<sub>4</sub> exhibits a high average refractive index of <i>n</i><sub>D</sub> = 2.20, at λ = 589 nm. Furthermore, <i>in situ</i> high-temperature powder X-ray diffraction experiments enabled the study of the thermal expansion tensors of GaTaO<sub>4</sub> and GaNbO<sub>4</sub>, as well as the ability to relate them with structural features

    Superstructure of Mullite-type KAl<sub>9</sub>O<sub>14</sub>

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    Large whiskers of a new KAl<sub>9</sub>O<sub>14</sub> polymorph with mullite-type structure were synthesized. The chemical composition of the crystals was confirmed by energy-dispersive X-ray spectroscopy, and the structure was determined using single-crystal X-ray diffraction. Nanosized twin domains and one-dimensional diffuse scattering were observed utilizing transmission electron microscopy. The compound crystallizes in space group <i>P</i>2<sub>1</sub>/<i>n</i> (<i>a</i> = 8.1880(8), <i>b</i> = 7.6760(7), <i>c</i> = 8.7944(9) Å, β = 110.570(8)°, <i>V</i> = 517.50(9) Å<sup>3</sup>, <i>Z</i> = 2). Crystals of KAl<sub>9</sub>O<sub>14</sub> exhibit a mullite-type structure with linear edge-sharing AlO<sub>6</sub> octahedral chains connected with groups of two AlO<sub>4</sub> tetrahedra and one AlO<sub>5</sub> trigonal bipyramid. Additionally, disproportionation of KAl<sub>9</sub>O<sub>14</sub> into K β-alumina and corundum was observed using in situ high-temperature optical microscopy and Raman spectroscopy
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