Fingerprints of composite fermion Lambda levels in scanning tunneling microscopy

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

Physical Review B Pub Date : 2024-08-14 DOI:10.1103/physrevb.110.l081107

Songyang Pu, Ajit C. Balram, Yuwen Hu, Yen-Chen Tsui, Minhao He, Nicolas Regnault, Michael P. Zaletel, Ali Yazdani, Zlatko Papić

引用次数: 0

Abstract

A composite fermion (CF) is a topological quasiparticle that emerges from a nonperturbative attachment of vortices to electrons in strongly correlated two-dimensional materials. Similar to noninteracting fermions that form Landau levels in a magnetic field, CFs can fill analogous “Lambda” levels, giving rise to the fractional quantum Hall (FQH) effect of electrons. Here, we show that Lambda levels can be directly visualized through the characteristic peak structure in the signal obtained via spectroscopy with scanning tunneling microscopy (STM) on a FQH state. Complementary to transport, which probes the low-energy properties of CFs, we show that high-energy features in STM spectra can be interpreted in terms of Lambda levels. We numerically demonstrate that STM spectra can be accurately modeled using Jain's CF theory. Our results show that STM provides a powerful tool for revealing the anatomy of FQH states and identifying physics beyond the noninteracting CF paradigm.

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扫描隧道显微镜中的复合费米子 Lambda 水平指纹

复合费米子（CF）是一种拓扑准粒子，它是由强相关二维材料中电子上的涡旋非全扰动附着产生的。与在磁场中形成朗道水平的非相互作用费米子类似，复合费米子可以填充类似的 "Lambda "水平，从而产生电子的分数量子霍尔效应（FQH）。在这里，我们展示了可以通过扫描隧道显微镜（STM）对 FQH 状态进行光谱分析获得的信号中的特征峰结构来直接观察 Lambda 水平。作为对探测 CF 低能特性的传输的补充，我们表明 STM 光谱中的高能特征可以用 Lambda 水平来解释。我们从数值上证明了 STM 光谱可以使用 Jain 的 CF 理论进行精确建模。我们的研究结果表明，STM 为揭示 FQH 状态的解剖结构和识别非相互作用 CF 范式之外的物理学提供了一个强大的工具。

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

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