Effects of the counter-cation nature and preparation method on the structure of La2Zr2O7

Lanthanum zirconate with a pyrochlore structure exhibits interesting thermal and structural properties for thermal barrier coating applications operating at high temperature. This study focused on the synthesis of La 2 Zr 2 O 7 powders by soft chemistry (citrate, coprecipitation, and sol–gel methods...

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Veröffentlicht in:	Journal of materials science 2015-01, Vol.50 (1), p.463-475
Hauptverfasser:	Duarte, William, Meguekam, Ariane, Colas, Maggy, Vardelle, Michel, Rossignol, Sylvie
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Sprache:	eng
Schlagworte:	Cations Characterization and Evaluation of Materials Chemical Sciences Chemical synthesis Chemistry and Materials Science Classical Mechanics Crystallography and Scattering Methods Engineering Sciences Ethanol High temperature Lanthanum Material chemistry Materials Materials Science Organic chemistry Original Paper Particle size Polymer Sciences Precursors Sol-gel processes Solid Mechanics Solvents Strong interactions (field theory) Thermal barrier coatings
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creator	Duarte, William Meguekam, Ariane Colas, Maggy Vardelle, Michel Rossignol, Sylvie
description	Lanthanum zirconate with a pyrochlore structure exhibits interesting thermal and structural properties for thermal barrier coating applications operating at high temperature. This study focused on the synthesis of La 2 Zr 2 O 7 powders by soft chemistry (citrate, coprecipitation, and sol–gel methods), and the effects of the solvent and the nature of the precursors used on the powder properties were investigated. The nature of the counter-cation influenced the structural phase of the compound. A low polarizable counter-cation (chloride) permitted the elaboration of a pyrochlore structure within a larger range of parameters compared with highly polarizable counter-cations (nitrate and acetate). Moreover, the nature of the solvent, and specifically the strength of the interactions within it, had an impact on the particle size. Specifically, the use of water, which is a solvent with strong interactions, led to a smaller particle size than the use of ethanol, which has weaker interactions. Based on these results, the crystalline phase of the powders can be predicted as a function of the precursor and the solvent used for the different synthesis routes, and the particle size can be used to evaluate the reactivity of the powders.
doi_str_mv	10.1007/s10853-014-8606-4
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This study focused on the synthesis of La 2 Zr 2 O 7 powders by soft chemistry (citrate, coprecipitation, and sol–gel methods), and the effects of the solvent and the nature of the precursors used on the powder properties were investigated. The nature of the counter-cation influenced the structural phase of the compound. A low polarizable counter-cation (chloride) permitted the elaboration of a pyrochlore structure within a larger range of parameters compared with highly polarizable counter-cations (nitrate and acetate). Moreover, the nature of the solvent, and specifically the strength of the interactions within it, had an impact on the particle size. Specifically, the use of water, which is a solvent with strong interactions, led to a smaller particle size than the use of ethanol, which has weaker interactions. 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This study focused on the synthesis of La 2 Zr 2 O 7 powders by soft chemistry (citrate, coprecipitation, and sol–gel methods), and the effects of the solvent and the nature of the precursors used on the powder properties were investigated. The nature of the counter-cation influenced the structural phase of the compound. A low polarizable counter-cation (chloride) permitted the elaboration of a pyrochlore structure within a larger range of parameters compared with highly polarizable counter-cations (nitrate and acetate). Moreover, the nature of the solvent, and specifically the strength of the interactions within it, had an impact on the particle size. Specifically, the use of water, which is a solvent with strong interactions, led to a smaller particle size than the use of ethanol, which has weaker interactions. 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subjects	Cations Characterization and Evaluation of Materials Chemical Sciences Chemical synthesis Chemistry and Materials Science Classical Mechanics Crystallography and Scattering Methods Engineering Sciences Ethanol High temperature Lanthanum Material chemistry Materials Materials Science Organic chemistry Original Paper Particle size Polymer Sciences Precursors Sol-gel processes Solid Mechanics Solvents Strong interactions (field theory) Thermal barrier coatings
title	Effects of the counter-cation nature and preparation method on the structure of La2Zr2O7
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