Magneto-optical conductivity of a band-inverted charge transfer insulator

IF 3.7 2区物理与天体物理 Q1 Physics and Astronomy

Physical Review B Pub Date : 2024-07-31 DOI:10.1103/physrevb.110.045445

Chang Liu, Sha-Sha Ke, Yong Guo, Xiao-Tao Zu, Sean Li, Hai-Feng Lü

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Abstract

Recently, quantum anomalous Hall state has been observed in moiré transition metal dichalcogenide bilayers. Its topological physics can be explained by a band-inverted charge transfer insulator model, in which the topological phase transition occurs in the presence of the band inversion. Starting from an effective three-band low-energy model, we investigate the Landau levels and the magneto-optical conductivity of a band-inverted charge transfer insulator on the honeycomb lattice. We derive the real and imaginary parts of the longitudinal conductivity and Hall conductivity using Kubo formalism. We find that the magneto-optical conductivity indicates a discontinuity at the point of band inversion in the low-frequency regime, which can serve as a probe for band topology. It is shown that the charge transfer gap, chemical potential, and magnetic field have a sensitive effect on the magneto-optical conductivity. The unique band structure also changes the peaks in the imaginary part of the Hall conductivity into two distinct contributions of opposite signs. We also study the relationship of the band-inversion signature and transport properties and highlight its distinct features that can be probed experimentally.

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带逆电荷转移绝缘体的磁光传导性

最近，在莫伊里过渡金属二卤化物双层膜中观察到了量子反常霍尔态。它的拓扑物理特性可以用带反转电荷转移绝缘体模型来解释，其中拓扑相变发生在带反转的情况下。从有效的三带低能模型出发，我们研究了蜂窝晶格上带反转电荷转移绝缘体的朗道水平和磁光传导性。我们利用久保形式主义推导出了纵向电导率和霍尔电导率的实部和虚部。我们发现，磁光电导率表明在低频带反转点存在不连续性，这可以作为带拓扑结构的探针。研究表明，电荷转移间隙、化学势和磁场对磁光传导性有敏感的影响。独特的带状结构还将霍尔电导率虚部的峰值变为两个符号相反的不同贡献。我们还研究了带反转特征与传输特性之间的关系，并强调了其可通过实验探测的明显特征。

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来源期刊

Physical Review B 物理-物理：凝聚态物理

CiteScore

6.70

自引率

32.40%

发文量

审稿时长

3.0 months

期刊介绍： Physical Review B (PRB) is the world’s largest dedicated physics journal, publishing approximately 100 new, high-quality papers each week. The most highly cited journal in condensed matter physics, PRB provides outstanding depth and breadth of coverage, combined with unrivaled context and background for ongoing research by scientists worldwide. PRB covers the full range of condensed matter, materials physics, and related subfields, including: -Structure and phase transitions -Ferroelectrics and multiferroics -Disordered systems and alloys -Magnetism -Superconductivity -Electronic structure, photonics, and metamaterials -Semiconductors and mesoscopic systems -Surfaces, nanoscience, and two-dimensional materials -Topological states of matter