Al2O3 - FeO - TiO2体系的亚固体结构分析

O. Borysenko, S. Logvinkov, G. Shabanova
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引用次数: 0

摘要

为了合成具有特定相组成和性能的复合材料,迫切需要研究多组分体系的亚固体结构。由于对Al2O3 - FeO - TiO2体系的认识不足,人们对该体系的结构以及在不同温度范围内体系中发生的过程产生了研究兴趣。对Al2O3 - FeO - TiO2体系进行了热力学分析,发现体系在1413k以下、1413k - 1537k以下、1537k - 1530k以下、1630k - 1630k以下、1630k - 2076k以下和2076k以上5个温度区间内的初等三角形分布发生了变化。分析了该体系及其相的主要几何拓扑特征:初等三角形的面积、不对称程度、相存在区域的面积和相存在的概率。结果表明,FeAl2O4 - Fe2TiO4 - FeO初等三角形在温度为2076 K时仍具有较大的面积和较小的不对称性,而在温度为1413 K时FeAl2O4相的存在概率最高;所有这些都表明了在该区域预测合成材料相组成的可靠性,并且不需要特殊的技术条件来保证给药的准确性和前体均质化的时间。在1537 ~ 1630 К温度范围内,Al2TiO5 - FeAl2O4 - TiO2初等三角形的面积最大,但在1630 K以上的温度范围内,连接发生重排。在这个范围内,研究人员可能会对FeTi2O5 - Al2TiO5 - FeTiO3初等三角形感兴趣,它具有最小的面积和最大的不对称程度。当然,可以通过额外的计算来确定成分是否属于两个初等三角形Al2TiO5 - FeAl2O4 - TiO2和FeTi2O5 - Al2TiO5 - FeTiO3的结合部,在该区域工作时必须严格遵守特殊的质量制备和合成工艺方法。对于耐热性提高的刚玉耐火材料和刚玉基材料,应计算其成分是否属于Al2O3 - Al2TiO5 - FeAl2O4(温度范围1537 ~ 1630 K)和Al2TiO5 - FeTiO3 - Al2O3或FeTiO3 - Al2O3 - FeAl2O4(温度在1630 K以上)的结合体区域,计算数据在温度为2076 K以上,因为没有证明Al4TiO8化合物的存在。是推荐性的,需要进一步的理论和实践研究。根据所获得的结果,对获得具有所需相组成和所需性能的新材料的最佳成分范围给出了建议。这将有助于开发用于制造复合材料的最新资源节约型技术。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Analysis of the subsolidus structure in the Al2O3 – FeO – TiO2 system
The study of the subsolidus structure of multicomponent systems for the synthesis of composite materials with specified phase composition and properties is urgent. Insufficient knowledge of the Al2O3 – FeO – TiO2 system arouses research interest in the structure of the system, as well as in the processes that occur in the system in different temperature ranges. A thermodynamic analysis of the Al2O3 – FeO – TiO2 system was carried out and it was found that the partition of the system into elementary triangles changes in five temperature ranges: I – up to a temperature of 1413 K, II – in the temperature range 1413 – 1537 K, III – 1537 – 1630 K, IV – 1630 – 2076 K and V – above the temperature of 2076 K. The main geometrical-topological characteristics of the subsolidus structure of the system and its phases were analyzed: the areas of elementary triangles, the degree of their asymmetry, the area of regions in which phases exist and the probability of the existence of phases. It was found that the FeAl2O4 – Fe2TiO4 – FeO elementary triangle with a relatively large area and a fairly small degree of asymmetry remained unchanged up to a temperature of 2076 K and the FeAl2O4 phase had the highest probability of existence above a temperature of 1413 K; all this indicates the reliability of predicting the phase composition of synthesized materials in this area and does not require special technological conditions for the accuracy of dosing and the time for homogenization of precursors. In the temperature range 1537 – 1630 К, the Al2TiO5 – FeAl2O4 – TiO2 elementary triangle has the largest area, but rearrangement of the connections occurs above a temperature of 1630 K. In this range, researchers may be interested in the FeTi2O5 – Al2TiO5 – FeTiO3 elementary triangle, which has the smallest area and the greatest degree of asymmetry. Of course, it is possible to perform additional calculations to determine whether the compositions belong to the joint area of two elementary triangles Al2TiO5 – FeAl2O4 – TiO2 and FeTi2O5 – Al2TiO5 – FeTiO3, special technological methods of mass preparation and synthesis must be strictly observed in working in this area. For corundum refractories and corundum-based materials with increased heat resistance, it is advisable to calculate whether the compositions belong to the joint region Al2O3 – Al2TiO5 – FeAl2O4 (in the temperature range 1537 – 1630 K) and Al2TiO5 – FeTiO3 – Al2O3 or FeTiO3 – Al2O3 – FeAl2O4 (above a temperature of 1630 K). The calculated data obtained above a temperature of 2076 K, as a consequence of non-proving the existence of the Al4TiO8 compound, are of recommendatory nature and require further theoretical and practical studies. Based on the results obtained, recommendations are given on the range of compositions that are optimal for obtaining new materials with the required phase composition and desired properties. This will contribute to the development of the latest resource-saving technologies for the manufacture of composite materials.
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