砷化镉超薄薄膜中的零场维格纳固体证据

IF 11.6 1区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY

Physical Review X Pub Date : 2024-11-07 DOI:10.1103/physrevx.14.041037

Simon Munyan, Sina Ahadi, Binghao Guo, Arman Rashidi, Susanne Stemmer

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引用次数: 0

摘要

量子维格纳晶体是一种多体状态，库仑斥力淬灭了电子的动能，使电子结晶成晶格。在实验中实现零磁场下的量子维格纳晶体一直是人们孜孜以求的目标。在这里，我们报告了在零磁场下砷化镉（Cd3As2）超薄薄膜中出现维格纳固体的实验证据。我们的研究表明，有限偏压会使畴沉积，并产生异常尖锐的阈值电流-电压行为。磁滞和电压波动表明畴运动跨越了针销电势，并随着热波动克服电势而在有限温度下消失。施加一个小磁场就会破坏维格纳固体，从而指向一个非传统的起源。我们利用朗道级光谱学证明，随着薄膜厚度的减小，维格纳固体的形成与拓扑转变密切相关。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Evidence of Zero-Field Wigner Solids in Ultrathin Films of Cadmium Arsenide

查看原文本刊更多论文

Evidence of Zero-Field Wigner Solids in Ultrathin Films of Cadmium Arsenide

The quantum Wigner crystal is a many-body state where Coulombic repulsion quenches the kinetic energy of electrons, causing them to crystallize into a lattice. Experimental realization of a quantum Wigner crystal at zero magnetic field has been a long-sought goal. Here, we report on the experimental evidence of a Wigner solid in ultra-thin films of cadmium arsenide (

C d 3 A s 2

) at zero magnetic field. We show that a finite bias depins the domains and produces an unusually sharp-threshold current-voltage behavior. Hysteresis and voltage fluctuations point to domain motion across the pinning potential and disappear at finite temperature as thermal fluctuations overcome the potential. The application of a small magnetic field destroys the Wigner solid, pointing to an unconventional origin. We use Landau-level spectroscopy to show that the formation of the Wigner solid is closely connected to a topological transition as the film thickness is reduced.

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来源期刊

Physical Review X PHYSICS, MULTIDISCIPLINARY-

CiteScore

24.60

自引率

1.60%

发文量

197

审稿时长

3 months

期刊介绍： Physical Review X (PRX) stands as an exclusively online, fully open-access journal, emphasizing innovation, quality, and enduring impact in the scientific content it disseminates. Devoted to showcasing a curated selection of papers from pure, applied, and interdisciplinary physics, PRX aims to feature work with the potential to shape current and future research while leaving a lasting and profound impact in their respective fields. Encompassing the entire spectrum of physics subject areas, PRX places a special focus on groundbreaking interdisciplinary research with broad-reaching influence.