Simulation of Intrinsic Defects and Cd Site Occupation in LaIn3 and LuIn3

Diffusion Foundations Pub Date : 2020-05-01 DOI:10.4028/www.scientific.net/DF.27.40

M. Zacate, John P. Bevington, G. Collins

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引用次数: 2

Abstract

In previous work, perturbed angular correlation spectroscopy (PAC) was used to determine jump rates of 111Cd, the daughter of the 111In radiotracer, in the series of phases RIn3 (R = rare-earth element) through nuclear quadrupole relaxation. Greater relaxation, indicating faster Cd jump rates, was observed in heavy rare-earths for compositions more deficient in indium, as would be expected for diffusion mediated by vacancies on the In sublattice. On the other hand, greater relaxation was observed for light rare-earths (R = La, Ce, and Pr) for compositions with excess indium, suggesting Cd diffusion is mediated there by a different mechanism. In this work, computer simulations were carried out to better understand the nature of the relaxation observed for the light rare-earths and the origin of the change in behavior across the rare-earth series. As a first step, formation enthalpies of intrinsic defects were calculated using density functional theory (DFT) for series end-members LaIn3 and LuIn3. Both compounds were found to exhibit Schottky thermal disorder. Additional DFT simulations show that the binding enthalpy between In-and R-vacancies is larger in LaIn3 than in LuIn3, suggesting that diffusion in LaIn3 might be mediated by divacancies. Site enthalpies of Cd also were calculated, and it was found more favorable energetically for Cd to occupy the In sublattice than the R sublattice in both end-member phases.

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LaIn3和LuIn3内部缺陷和Cd占位的模拟

在以前的工作中，用摄动角相关光谱(PAC)测定了111In放射性示踪剂的子代111Cd通过核四极弛豫在相RIn3 (R =稀土元素)系列中的跳变率。更大的弛豫，表明更快的Cd跳跃速率，在重稀土成分中观察到更缺乏铟，正如预期的扩散介导的空位在铟亚晶格上。另一方面，对于含有过量铟的轻稀土(R = La, Ce和Pr)，观察到更大的弛豫，这表明Cd的扩散是通过不同的机制介导的。在这项工作中，进行了计算机模拟，以更好地理解在轻稀土中观察到的弛豫的性质以及在稀土系列中行为变化的起源。首先，利用密度泛函理论(DFT)计算了系列端元LaIn3和LuIn3的本征缺陷形成焓。这两种化合物都表现出肖特基热失序。另外的DFT模拟表明，LaIn3中in -和r -空位之间的结合焓比LuIn3大，这表明LaIn3中的扩散可能是由空位介导的。同时计算了Cd的空位焓，发现Cd在两个端元相中占据In亚晶格比占据R亚晶格在能量上更有利。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Diffusion Foundations

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