SCS法合成稀土金属氧化物多组分陶瓷固溶体的制备及其力学性能

IF 2.7 Q1 MATERIALS SCIENCE, CERAMICS
V. Zhuravlev, L. Ermakova, R. Samigullina, A. Ermakov
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引用次数: 0

摘要

研究了用甘氨酸和柠檬酸溶液燃烧合成法合成稀土(RE)金属氧化物(Nd、Sm、Eu、Gd、Dy和Ho)的多组分固溶体细粉末,用于制备陶瓷材料。测定了具有C型立方结构的4-、5-和6-组分熵稳定稀土氧化物(REO)的合成参数。具有C型结构的熵稳定氧化物(ESOs)的稳定性不仅取决于重稀土金属的量,还取决于样品的加热/冷却速率。C型REO结构向B型(单斜)或H型(六方)结构变体的多态性转变的温度可以用方程T(°C)=0.0214Vcr2−62.737Vcr+46390来描述,其中Vcr是具有C型结构的氧化物的晶胞体积,而与固溶体中的阳离子数量无关。高达1250°C的高温热分析表明,分散的粉末含有碱性碳酸盐的杂质,以及在SCS反应中形成的RE金属的水合碳酸盐和X射线无定形碳,在储存过程中也会与空气水分发生反应。研究了ESO相和阳离子组成对陶瓷的形貌、孔隙率和显微硬度的影响。较高熵的氧化物形成具有较高密度、显微硬度和较小尺寸颗粒团聚体的样品。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Preparation and Mechanical Characteristics of Multicomponent Ceramic Solid Solutions of Rare Earth Metal Oxides Synthesized by the SCS Method
A study into the use of the Solution Combustion Synthesis (SCS) method with glycine and citric acid to synthesize fine powders of multicomponent solid solutions of oxides of rare earth (RE) metals (Nd, Sm, Eu, Gd, Dy, and Ho) for the preparation of ceramic materials is presented. Synthesis parameters of 4-, 5-, and 6-component entropy-stabilized rare earth oxides (REOs) with a C-type cubic structure are determined. The stability of entropy-stabilized oxides (ESOs) with a C-type structure is shown to depend not only on heavy RE metal quantity, but also on the rate of heating/cooling of the samples. The temperature of the polymorphic transformation of C-type REO structures into B-type (monoclinic) or H-type (hexagonal) structural variants can be described by the equation T (°C) = 0.0214Vcr2 − 62.737Vcr + 46390, where Vcr is the unit cell volume of an oxide with a C-type structure regardless of the number of cations in the solid solution. High-temperature thermal analysis up to 1250 °C revealed that dispersed powders, which contain impurities of basic carbonates along with hydroxocarbonates of RE metals and X-ray amorphous carbon formed during SCS reactions, also react with air moisture during storage. The influence of the ESO phase and cationic composition on the morphology, porosity and microhardness of ceramics was studied. Higher-entropy oxides form samples with higher density, microhardness and a smaller size of particle agglomerates.
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来源期刊
CiteScore
3.00
自引率
7.10%
发文量
66
审稿时长
10 weeks
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