α-Fe2O3中点缺陷的热动力学

IF 2.9 Q3 CHEMISTRY, PHYSICAL
A. Banerjee, Edward F. Holby, A. Kohnert, S. Srivastava, M. Asta, B. Uberuaga
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引用次数: 0

摘要

氧化物中的点缺陷形成和迁移控制着从腐蚀动力学和辐射损伤演变到电子性能的广泛现象。在本研究中,我们使用密度泛函理论研究了赤铁矿(α -Fe2O3)中阴离子和正离子点缺陷的热力学和动力学,赤铁矿是一种重要的铁氧化物,与钢的腐蚀和水分解应用高度相关。这些计算表明,点缺陷的迁移势垒随着电荷状态的变化而显著变化,特别是对于阳离子间隙。此外,我们发现了该材料中许多点缺陷的多种可能的迁移途径,这与刚玉晶体结构的低对称性有关。研究了可能的渗透路径,利用势垒来确定远程扩散的大小和各向异性。我们的研究结果表明,赤铁矿的质量输运具有高度的各向异性,有利于沿晶体c轴的扩散。此外,我们用迄今为止报道的最大的Fe2O3超级单体考虑了点缺陷形成的能量学。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Thermokinetics of point defects in α-Fe2O3
Point defect formation and migration in oxides governs a wide range of phenomena from corrosion kinetics and radiation damage evolution to electronic properties. In this study, we examine the thermodynamics and kinetics of anion and cation point defects using density functional theory in hematite ( α -Fe2O3), an important iron oxide highly relevant in both corrosion of steels and water-splitting applications. These calculations indicate that the migration barriers for point defects can vary significantly with charge state, particularly for cation interstitials. Additionally, we find multiple possible migration pathways for many of the point defects in this material, related to the low symmetry of the corundum crystal structure. The possible percolation paths are examined, using the barriers to determine the magnitude and anisotropy of long-range diffusion. Our findings suggest highly anisotropic mass transport in hematite, favoring diffusion along the c-axis of the crystal. In addition, we have considered the point defect formation energetics using the largest Fe2O3 supercell reported to date.
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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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