掺铪氧化镥中的缺陷和相应的电子陷阱:一个广义梯度近似研究。

A. Shyichuk, Dagmara Kulesza, E. Zych
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引用次数: 1

摘要

据报道,许多基于lu2o3的材料能够有效地捕获由特定掺杂剂或自然缺陷形成的亚稳激发态的激发态载流子。多年来,我们收集了大量的实验数据,为运用计算化学处理这一问题提供了坚实的基础。利用密度泛函理论(DFT)计算和先进的元广义梯度近似(mGGA)泛函分析了掺Hf的立方Lu2O3中的电子俘获。考虑了掺杂剂的单个离子和最近邻的掺杂剂离子对。分析了间质阴离子O2-、Cl-的作用。在大多数分析的情况下,附加的电子电荷被定位在掺杂点。然而,在许多研究的情况下,掺杂/缺陷态与导带重叠,不能对应于电子捕获。C3i局部对称的Lu位({\rm Hf}^{\times}_{\rm Lu}-C_{\rm 3i}})的Hf3+离子对应于0.8 ~ 0.9 eV的中等陷阱深度。此外,还存在与较深(1.1 ~ 1.4 eV)陷阱相对应的复合缺陷。明确的深阱(1.5 ~ 1.8 eV)对应于离子空洞中Hf掺杂的体系,并伴有两个间隙氧原子。结果表明,碱性“Hf-取代物- lu”掺杂不太可能与实验中观察到的Lu2O3:Tb,Hf和Lu2O3:Pr,Hf的深阱相对应,必须涉及更复杂的缺陷。
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Defects in hafnium-doped lutetium oxide and the corresponding electron traps: a meta-generalized gradient approximation study.
A number of Lu2O3-based materials were reported to present efficient capability of trapping excited charge carriers in metastable excited states formed either by specific dopants or naturally occurring defects. Over the years, abundant experimental data have been collected, which were taken as a solid ground to treat the problem using computational chemistry. Density functional theory (DFT) calculations with an advanced meta generalized gradient approximation (mGGA) functional were used to analyze electron trapping in cubic Lu2O3 doped with Hf. Individual ions of dopant and nearest-neighbor dopant ion pairs were considered. The effects of interstitial anions such as O2- and Cl- were analyzed. In most of the analyzed cases the additional electron charge is localized at the dopant site. However, in many of the studied cases, the dopant/defect states overlap with the conduction band and cannot correspond to electron trapping. The Hf3+ ion in the Lu site of C3i local symmetry ({\rm Hf}^{\times}_{{\rm Lu}-C_{\rm 3i}}) corresponds to a moderate trap depth of 0.8-0.9 eV. Several composite defects corresponding to deeper (1.1-1.4 eV) traps also exist. Unambiguous deep traps (1.5-1.8 eV) correspond to systems with Hf dopant in the cationic void, accompanied by two interstitial oxygen atoms. The results thus indicate that basic `Hf-substitutes-Lu' doping is unlikely to correspond to the deep traps observed experimentally in Lu2O3:Tb,Hf andLu2O3:Pr,Hf and more complex defects must be involved.
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