Hofstadter Butterflies and Metal/Insulator Transitions for Moiré Heterostructures

IF 1.3 3区物理与天体物理 Q2 PHYSICS, MATHEMATICAL

Annales Henri Poincaré Pub Date : 2024-11-10 DOI:10.1007/s00023-024-01509-z

Simon Becker, Lingrui Ge, Jens Wittsten

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Abstract

We consider a tight-binding model recently introduced by Timmel and Mele (Phys Rev Lett 125:166803, 2020) for strained moiré heterostructures. We consider two honeycomb lattices to which layer antisymmetric shear strain is applied to periodically modulate the tunneling between the lattices in one distinguished direction. This effectively reduces the model to one spatial dimension and makes it amenable to the theory of matrix-valued quasi-periodic operators. We then study the charge transport and spectral properties of this system, explaining the appearance of a Hofstadter-type butterfly and the occurrence of metal/insulator transitions that have recently been experimentally verified for non-interacting moiré systems (Wang et al. in Nature 577:42–46, 2020). For sufficiently incommensurable moiré lengths, described by a diophantine condition, as well as strong coupling between the lattices, which can be tuned by applying physical pressure, this leads to the occurrence of localization phenomena.

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微波异质结构的霍夫施塔特蝴蝶和金属/绝缘体跃迁

我们考虑了Timmel和Mele （Phys Rev Lett 125:166803, 2020）最近提出的一种紧结合模型。我们考虑了两个蜂窝晶格，在蜂窝晶格上施加一层反对称剪切应变来周期性地调制晶格之间在一个特定方向上的隧穿。这有效地将模型简化到一个空间维度，使其符合矩阵值拟周期算子理论。然后，我们研究了该系统的电荷传输和光谱特性，解释了霍夫施塔特型蝴蝶的出现，以及最近在非相互作用的moir系统中实验验证的金属/绝缘体跃迁的发生（Wang et al. in Nature 577:42 - 46,2020）。对于由丢芬图条件描述的不可通约的莫尔长度，以及可以通过施加物理压力来调节的晶格之间的强耦合，这将导致局域化现象的发生。

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

Annales Henri Poincaré 物理-物理：粒子与场物理

CiteScore

3.00

自引率

6.70%

发文量

108

审稿时长

6-12 weeks

期刊介绍： The two journals Annales de l''Institut Henri Poincaré, physique théorique and Helvetica Physical Acta merged into a single new journal under the name Annales Henri Poincaré - A Journal of Theoretical and Mathematical Physics edited jointly by the Institut Henri Poincaré and by the Swiss Physical Society. The goal of the journal is to serve the international scientific community in theoretical and mathematical physics by collecting and publishing original research papers meeting the highest professional standards in the field. The emphasis will be on analytical theoretical and mathematical physics in a broad sense.