Dirac fermion spectrum of the fractional quantum Hall states

IF 0.9 4区物理与天体物理 Q4 PHYSICS, CONDENSED MATTER

Condensed Matter Physics Pub Date : 2023-05-25 DOI:10.5488/CMP.26.23703

I. N. Karnaukhov

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Abstract

Applying a unified approach, we study the integer quantum Hall effect (IQHE) and fractional quantum Hall effect (FQHE) in the Hofstadter model with short range interactions between fermions. An effective field, that takes into account the interaction between fermions, is determined by both amplitude and phase. Its amplitude is proportional to the interaction strength, the phase corresponds to the minimum energy. In fact, the problem is reduced to the Harper equation with two different scales: the first is a magnetic scale with the cell size corresponding to a unit quantum magnetic flux, the second scale determines the inhomogeneity of the effective field, forms the steady fine structure of the Hofstadter spectrum and leads to the realization of fractional quantum Hall states. In a sample of finite size with open boundary conditions, the fine structure of the Hofstadter spectrum consists of the Dirac branches of the fermion excitations and includes the fine structure of the edge chiral modes. The Chern numbers of the topological Hofstadter bands are conserved during the formation of their fine structure. The edge modes are formed into the Hofstadter bands. They connect the nearest-neighbor subbands and determine the conductance for the fractional filling.

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分数量子霍尔态的狄拉克费米子谱

采用统一的方法，研究了费米子之间短距离相互作用的Hofstadter模型中的整数量子霍尔效应(IQHE)和分数量子霍尔效应(FQHE)。考虑费米子之间相互作用的有效场是由振幅和相位共同决定的。其振幅与相互作用强度成正比，相位对应于最小能量。实际上，这个问题可以简化为两个不同尺度的Harper方程:第一个尺度是磁尺度，其胞体大小对应于一个单位量子磁通量，第二个尺度决定了有效场的非均匀性，形成了霍夫施塔特谱的稳定精细结构，导致分数阶量子霍尔态的实现。在开放边界条件下的有限尺寸样本中，霍夫施塔特谱的精细结构包括费米子激发的狄拉克分支和边缘手性模式的精细结构。拓扑霍夫施塔特带的陈恩数在其精细结构形成过程中是守恒的。边缘模形成霍夫施塔特带。它们连接最近邻子带并确定分数填充的电导。

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

Condensed Matter Physics 物理-物理：凝聚态物理

CiteScore

1.10

自引率

16.70%

发文量

审稿时长

1 months

期刊介绍： Condensed Matter Physics contains original and review articles in the field of statistical mechanics and thermodynamics of equilibrium and nonequilibrium processes, relativistic mechanics of interacting particle systems.The main attention is paid to physics of solid, liquid and amorphous systems, phase equilibria and phase transitions, thermal, structural, electric, magnetic and optical properties of condensed matter. Condensed Matter Physics is published quarterly.