YAG-Ceramic Powders — Size-Reduction Influence on Optical Ceramic Properties

IF 0.6 4区 材料科学 Q4 MATERIALS SCIENCE, CERAMICS Glass and Ceramics Pub Date : 2024-04-29 DOI:10.1007/s10717-024-00637-6
V. E. Suprunchuk, A. A. Kravtsov, V. A. Lapin, V. A. Tarala, L. V. Tarala, E. V. Medyanik, F. F. Malyavin
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Abstract

The morphology and degree of agglomeration of the precursor and YAG-ceramic powders were investigated as functions of the grinding conditions, followed by an assessment of the influence of these parameters on the optical properties and structure of the ceramic. YAG-precursor powders were obtained by chemical coprecipitation. The morphology and size of the agglomerates and crystallites were assessed by means of scanning electron microscopy, laser diffraction analysis, x-ray diffraction analysis, and Brunauer–Emmett–Teller gas adsorption. It was discovered that grinding of the YAG precursor powders can decrease the degree of agglomeration of the ceramic powder. It was found that with a mass ratio of grinding balls to precursor powder of 6.75/1 and a mass ratio of the grinding medium to the mass of the precursor powder of 4.5/1, optimal conditions obtain for providing the necessary granulometric characteristics and the highest mono-dispersity. In summary, by such means the properties of YAG optical ceramic can be improved by using of an additional grinding stage for the powders synthesized by chemical deposition and by selecting suitable grinding modes.

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YAG 陶瓷粉末--尺寸缩小对光学陶瓷特性的影响
研究了研磨条件对前驱体和 YAG 陶瓷粉末的形态和团聚程度的影响,随后评估了这些参数对陶瓷的光学特性和结构的影响。YAG 前驱体粉末是通过化学共沉淀法获得的。通过扫描电子显微镜、激光衍射分析、X 射线衍射分析和布鲁瑙尔-艾美特-泰勒气体吸附法对团聚体和晶体的形态和大小进行了评估。研究发现,研磨 YAG 前驱体粉末可以降低陶瓷粉末的团聚程度。研究发现,如果研磨球与前驱体粉末的质量比为 6.75/1,研磨介质与前驱体粉末的质量比为 4.5/1,就能获得最佳条件,从而提供必要的粒度特性和最高的单分散性。总之,通过对化学沉积合成的粉末使用额外的研磨阶段和选择合适的研磨模式,可以改善 YAG 光学陶瓷的性能。
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来源期刊
Glass and Ceramics
Glass and Ceramics 工程技术-材料科学:硅酸盐
CiteScore
1.00
自引率
16.70%
发文量
85
审稿时长
6-12 weeks
期刊介绍: Glass and Ceramics reports on advances in basic and applied research and plant production techniques in glass and ceramics. The journal''s broad coverage includes developments in the areas of silicate chemistry, mineralogy and metallurgy, crystal chemistry, solid state reactions, raw materials, phase equilibria, reaction kinetics, physicochemical analysis, physics of dielectrics, and refractories, among others.
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