过渡金属杂质对二氧化钛中氧空位形成能量的组合效应

IF 1.8 4区材料科学 Q2 MATERIALS SCIENCE, CHARACTERIZATION & TESTING

Physical Mesomechanics Pub Date : 2024-02-08 DOI:10.1134/s1029959924010065

A. V. Bakulin, L. S. Chumakova, S. O. Kasparyan, S. E. Kulkova

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引用次数: 0

摘要

摘要采用密度泛函理论中的投影增强波法研究了 IVB-VIB 族过渡金属取代杂质对金红石型二氧化钛中氧空位形成能的组合效应。根据原子间距离估算了杂质原子的成对相互作用能。结果表明，Zr + Zr、Hf + Hf 和 Nb + Ta 原子对中的相互作用导致它们在晶格参数 a 的距离上沿 <100> 方向取向的能量偏好；Mo + Mo 和 Nb + Mo 原子对在晶格参数 c 的距离上沿 [001] 方向取向的能量偏好。研究发现，掺杂多个杂质引起的氧空位形成能的变化可以用单个杂质引起的能量变化之和除以一个系数来估算，该系数的值取决于杂质原子的相互排列。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Combination Effect of Transition Metal Impurities on Oxygen Vacancy Formation Energetics in TiO2

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Combination Effect of Transition Metal Impurities on Oxygen Vacancy Formation Energetics in TiO2

Abstract

The combination effect of substitutional impurities of group IVB–VIB transition metals on the oxygen vacancy formation energy in rutile titania was studied by the projector augmented wave method within density functional theory. The pair interaction energy of impurity atoms was estimated depending on the interatomic distance. It was shown that the interaction in the Zr + Zr, Hf + Hf and Nb + Ta pairs leads to the energy preference of their orientation along the <100> direction at a distance of the lattice parameter a. The Mo + Mo and Nb + Mo pairs prefer to orient along the [001] direction at a distance of the lattice parameter c. If the impurity atoms are farther than the third neighbors, then their interaction can be neglected. It was found that the change in the oxygen vacancy formation energy due to doping with several impurities can be estimated as the sum of the energy changes due to single impurity divided by a coefficient whose value depends on the mutual arrangement of the impurity atoms.

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来源期刊

Physical Mesomechanics Materials Science-General Materials Science

CiteScore

3.50

自引率

18.80%

发文量

期刊介绍： The journal provides an international medium for the publication of theoretical and experimental studies and reviews related in the physical mesomechanics and also solid-state physics, mechanics, materials science, geodynamics, non-destructive testing and in a large number of other fields where the physical mesomechanics may be used extensively. Papers dealing with the processing, characterization, structure and physical properties and computational aspects of the mesomechanics of heterogeneous media, fracture mesomechanics, physical mesomechanics of materials, mesomechanics applications for geodynamics and tectonics, mesomechanics of smart materials and materials for electronics, non-destructive testing are viewed as suitable for publication.