间隙合金 TixMo1 - xCyNz 的结构和特性研究

I. Khidirov, I. J. Jaksimuratov, F. K. Khallokov
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摘要

开发性能更佳的新材料需要对多组分间隙合金的晶体结构和性能进行研究。我们展示了对不同组成元素浓度比例的块状样品中 TixMo1 - xCyNz 间隙合金的晶体结构和显微硬度的研究结果。通过自蔓延高温合成获得的样品在 2600 K 下均匀退火 8 小时,并随炉一起冷却。中子衍射数据显示,合金具有面心立方晶体结构,其中 Ti 原子和 Mo 原子以及 C 原子和 N 原子相互取代,并分别统计位于 4b 位和八面体 4a 位。利用 X 射线衍射图样,采用 Rietveld 方法确定了晶粒大小、位错密度和微应变。样品的显微硬度用维氏硬度法测定。结果表明,威廉森-霍尔法和舍勒法测定的晶粒大小差别很大,而晶粒大小的增长模式以及位错密度和微应变的规律性变化则随着成分中各组分浓度的变化而变化。随着合金中碳含量的增加,晶粒尺寸和微应变减小,位错密度增加。结果表明,晶粒尺寸越小,位错密度越高,显微硬度就越趋向于碳含量的增加。随着 TixMo1 - xCyNz 中成分比例的变化,晶粒尺寸和微应变减小,位错密度增加,合金的显微硬度比二元碳化物和氮化钛增加了 1.5 - 2 倍。所获得的结果可用于在仪器和高温工程中使用间隙合金。
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Study of the structure and properties of interstitial alloys TixMo1 – xCyNz
Developing the new materials with improved properties suggests study of the crystal structure and properties of multicomponent interstitial alloys. We present the results of studying the crystal structure and microhardness of TixMo1 – xCyNz interstitial alloys in massive samples with different ratios of concentrations of constituent elements. The samples obtained by self-propagating high-temperature synthesis were subjected to homogenizing annealing at 2600 K for 8 h and cooled together with the furnace. Data of neutron diffraction revealed that the alloys have a face-centered cubic crystal structure in which Ti and Mo atoms, as well as C and N, are intersubstituted and statistically located in the 4b positions and octahedral 4a positions, respectively. The Rietveld method was used to determine crystallite sizes, dislocation densities, and microstrain using X-ray diffraction patterns. The microhardness of the samples was determined by the Vickers method. It is shown that the crystallite sizes determined by the Williamson-Hall and Scherrer methods differ significantly, whereas the patterns of crystallite growth in size, as well as regularities of changes in the dislocation density and microstrains follow change in the concentration of the components in the composition. As the carbon content in the alloy increases, the crystallite sizes and microstrains decrease, and the dislocation density increases. It is revealed that the smaller the crystallite size and the higher the dislocation density, the more microhardness is displaced towards increasing the carbon content. With a change in the ratio of components in TixMo1 – xCyNz as the crystallite size and microstrains decrease and dislocation density increases, the microhardness of the alloy increases by 1.5 – 2 times compared to binary carbide and titanium nitride. The results obtained can be applied to the use of interstitial alloys in instrumental and high-temperature engineering.
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