Comparative study of the crystallization behavior within the Na2O–Y2O3–ZrO2–SiO2 system during heating and cooling

Phase formation in glasses from the system Na2O–Y2O3–SiO2 with different concentrations of ZrO2 were studied concerning phase formation and crystallization behavior. The compositions were near the stoichiometry of NaYSi2O6. A comparison of microstructure and phase content after instant crystallizati...

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Veröffentlicht in:	CrystEngComm 2022-05, Vol.24 (24), p.4391-4398
Hauptverfasser:	Thieme, Christian, Dittmer, Marc, Höche, Thomas, Rampf, Markus, Rüssel, Christian
Format:	Artikel
Sprache:	eng
Schlagworte:	Apatite Comparative studies Composition Cooling Crystal growth Crystallization Enrichment Heating Microstructure Nucleation Precipitates Silicon dioxide Stoichiometry Yttrium oxide Zirconium dioxide
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description	Phase formation in glasses from the system Na2O–Y2O3–SiO2 with different concentrations of ZrO2 were studied concerning phase formation and crystallization behavior. The compositions were near the stoichiometry of NaYSi2O6. A comparison of microstructure and phase content after instant crystallization during slow cooling and after subsequent thermal annealing is given. The phases as well as the microstructure differ depending on thermal history. During cooling, predominantly a phase with apatite structure (NaY9Si6O26) precipitates and the residual glassy phase is enriched in ZrO2. The composition of the glassy phase was quantified and an enrichment of ZrO2 of slightly above five mol% was measured. ZrO2 concentrations >5 mol% lead to the precipitation of Y2O3 enriched ZrO2. A fast cooling of the melt results in glass formation without instant crystallization. Subsequent heating at temperatures below 1000 °C leads to the precipitation of an unknown phase whereas at higher temperatures NaYSi2O6 crystallizes. Two-step heating in terms of nucleation and crystal growth were performed and small ZrO2-particles have been formed homogenously within the sample volume. Those particles do not trigger volume crystallization within the glasses and surface crystallization is the predominant crystallization mechanism.
doi_str_mv	10.1039/d2ce00257d
format	Article
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The compositions were near the stoichiometry of NaYSi2O6. A comparison of microstructure and phase content after instant crystallization during slow cooling and after subsequent thermal annealing is given. The phases as well as the microstructure differ depending on thermal history. During cooling, predominantly a phase with apatite structure (NaY9Si6O26) precipitates and the residual glassy phase is enriched in ZrO2. The composition of the glassy phase was quantified and an enrichment of ZrO2 of slightly above five mol% was measured. ZrO2 concentrations >5 mol% lead to the precipitation of Y2O3 enriched ZrO2. A fast cooling of the melt results in glass formation without instant crystallization. Subsequent heating at temperatures below 1000 °C leads to the precipitation of an unknown phase whereas at higher temperatures NaYSi2O6 crystallizes. 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source	Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Apatite Comparative studies Composition Cooling Crystal growth Crystallization Enrichment Heating Microstructure Nucleation Precipitates Silicon dioxide Stoichiometry Yttrium oxide Zirconium dioxide
title	Comparative study of the crystallization behavior within the Na2O–Y2O3–ZrO2–SiO2 system during heating and cooling
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