大质量狄拉克费米子中标量势诱导拓扑转变的微观起源和标量霍尔效应

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

Physical Review B Pub Date : 2024-09-09 DOI:10.1103/physrevb.110.125117

Sumit Ghosh, Yuriy Mokrousov, Stefan Blügel

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引用次数: 0

摘要

我们对标量势诱导的大质量狄拉克费米子拓扑转变进行了系统研究。我们展示了标量势的分布如何操纵间隙或质量的特征，以及导致带反转的色散。这是由克莱因隧穿和反克莱因隧穿介导的，这使得它在本质上不同于导致拓扑安德森绝缘体的机制。在一维中，这可能导致边缘局域化的形成。在二维空间中，这会产生量子化霍尔效应。与传统霍尔效应不同的是，它是由标量相互作用诱导的，具有内在性质。因此，我们称之为标量霍尔效应。这有助于直接操纵拓扑不变量（如切尔恩数），以及在三维绝缘体中局部操纵边缘态，从而为调整源自非三维拓扑的物理观测指标提供了新的可能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Microscopic origin of scalar potential induced topological transition in massive Dirac fermions and scalar Hall effect

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Microscopic origin of scalar potential induced topological transition in massive Dirac fermions and scalar Hall effect

We present a systematic study of scalar potential induced topological transition in massive Dirac fermions. We show how a distribution of scalar potential can manipulate the signature of the gap or the mass, as well as the dispersion leading to a band inversion. This is mediated by the Klein tunneling as well as inverse Klein tunneling, which makes it inherently different from the mechanism leading to topological Anderson insulator. In one dimension it can lead to the formation of edge localization. In two dimensions this can give rise to the quantized Hall effect. Unlike conventional Hall effects, this is induced by a scalar interaction and is intrinsic in nature. Therefore, we call it a scalar Hall effect. This can facilitate direct manipulation of topological invariants, e.g., the Chern number, as well as the manipulation of the edge states locally in a trivial insulator and thus opens new possibilities for tuning physical observables which originate from the nontrivial topology.

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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