Anomalous delocalization of resonant states in graphene & the vacancy magnetic moment

IF 2.9 Q3 CHEMISTRY, PHYSICAL
M. Leccese, R. Martinazzo
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Abstract

Carbon atom vacancies in graphene give rise to a local magnetic moment of σ+π origin, whose magnitude is yet uncertain and debated. Partial quenching of π magnetism has been ubiquitously reported in periodic first principles calculations, with magnetic moments scattered in the range 1.0–2.0 µ B, slowly converging to the lower or the upper end, depending on how the diluted limit is approached. By contrast, (ensemble) density functional theory calculations on cluster models neatly converge to the value of 2 μB when increasing the system size. This stunning discrepancy has sparked a debate about the role of defect–defect interactions and self-doping, and about the importance of the self-interaction-error in the density-functional-theory description of the vacancy-induced states. Here, we settle this puzzle by showing that the problem has a fundamental, mono-electronic origin which is related to the special (periodic) arrangement of defects that results when using the slab-supercell approach. Specifically, we report the existence of resonant states that are anomalously delocalized over the lattice and that make the π midgap band unphysically dispersive, hence prone to self-doping and quenching of the π magnetism. Hybrid functionals fix the problem by widening the gap between the spin-resolved π midgap bands, without reducing their artificial widths. As a consequence, while reconciling the magnetic moment with expectations, they predict a spin-splitting which is one order of magnitude larger than found in experiments.
石墨烯共振态的反常离域&空位磁矩
石墨烯中的碳原子空位会产生σ+π起源的局部磁矩,其大小尚不确定,也存在争议。在周期第一性原理计算中,π磁性的部分猝灭已被普遍报道,磁矩分散在1.0–2.0µB的范围内,慢慢收敛到下端或上端,这取决于如何接近稀释极限。相比之下,聚类模型上的(系综)密度泛函理论计算巧妙地收敛到2的值 μB。这种惊人的差异引发了关于缺陷-缺陷相互作用和自掺杂的作用,以及自相互作用误差在空位诱导态的密度泛函理论描述中的重要性的辩论。在这里,我们通过证明这个问题有一个基本的单电子起源来解决这个难题,这与使用平板超晶胞方法时产生的缺陷的特殊(周期性)排列有关。具体地说,我们报道了共振态的存在,这些共振态在晶格上异常离域,使π中隙带不具有物理色散性,因此易于自掺杂和π磁性的猝灭。混合泛函通过扩大自旋分辨的π中隙带之间的间隙来解决这个问题,而不减少它们的人工宽度。因此,在调和磁矩与预期的同时,他们预测了比实验中发现的大一个数量级的自旋分裂。
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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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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