金红石
扩散
掺杂剂
材料科学
化学物理
有效扩散系数
扩散过程
各向异性
兴奋剂
凝聚态物理
化学
热力学
光学
物理
光电子学
创新扩散
有机化学
磁共振成像
放射科
医学
知识管理
计算机科学
作者
Linggang Zhu,Graeme J. Ackland,Qing‐Miao Hu,Jian Zhou,Zhimei Sun
出处
期刊:Physical review
[American Physical Society]
日期:2017-06-01
卷期号:95 (24)
被引量:5
标识
DOI:10.1103/physrevb.95.245201
摘要
Diffusion of dopants in rutile is the fundamental process that determines the performance of many devices in which rutile is used. The diffusion behavior is known to be highly sample-dependent, but the reasons for this are less well understood. Here, rutile is studied by using first-principles calculations, in order to unravel the microscopic origins of the diverse diffusion behaviors for different doping elements. Anomalous diffusion behavior in the open channel along [001] direction is found: larger atoms include Sc and Zr have lower energy barrier for diffusion via interstitial mechanism, apparently contradicting their known slow diffusion rate. To resolve this, we present an alternate model for the overall diffusion rate of the large-size dopants in rutile, showing that parallel to the [001] channel, it is limited by the formation of the interstitial states, whereas in the direction perpendicular to [001], it proceeds via a kick-out mechanism. By contrast, Co and Ni, prefer to stay in the interstitial site of rutile, and have conventional diffusion with a very small migration barrier in the [001] channel. This leads to highly anisotropic and fast diffusion. The diffusion mechanisms found in the present study can explain the diffusion data measured by experiments, and these findings provide novel understanding for the classic diffusion topic.
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