扭曲双层石墨烯中栅极定义的平带电荷载流子约束

Alexander Rothstein, Ammon Fischer, Anthony Achtermann, Eike Icking, Katrin Hecker, Luca Banszerus, Martin Otto, Stefan Trellenkamp, Florian Lentz, Kenji Watanabe, Takashi Taniguchi, Bernd Beschoten, Robin J. Dolleman, Dante M. Kennes, Christoph Stampfer
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引用次数: 0

摘要

接近魔幻角的扭曲双层石墨烯(tBLG)是研究相关电子相的有趣平台。这些相位是可门调谐的,与单粒子带隙隔离的平坦电子带的存在密切相关。这样就可以通过静电控制将电荷载流子限制在平坦带中,从而探索约束、带重正化、电子-电子相互作用和超晶格之间的相互作用,并有可能揭示这些电子相的关键机制。在这里,我们展示了门控平带电荷载流子在近魔术角 tBLG 中的傅里叶变换,这导致了 tBLG 中静电定义区域充电所产生的可调库仑阻塞共振。通过库仑共振测量,可以研究磁场诱导的源-漏储层状态密度量子振荡,从而深入了解 tBLG 的可门调谐费米面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Gate-defined flat-band charge carrier confinement in twisted bilayer graphene
Twisted bilayer graphene (tBLG) near the magic angle is an interesting platform to study correlated electronic phases. These phases are gate-tunable and are closely related to the presence of flat electronic bands, isolated by single-particle band gaps. This allows electrostatically controlled confinement of charge carriers in the flat bands to explore the interplay between confinement, band renormalisation, electron-electron interactions and the moir\'e superlattice, potentially revealing key mechanisms underlying these electronic phases. Here, we show gate-controlled flat-band charge carrier confinement in near-magic-angle tBLG, resulting in well-tunable Coulomb blockade resonances arising from the charging of electrostatically defined islands in tBLG. Coulomb resonance measurements allow to study magnetic field-induced quantum oscillations in the density of states of the source-drain reservoirs, providing insight into the gate-tunable Fermi surfaces of tBLG. Comparison with tight-binding calculations emphasises the importance of displacement-field-induced band renormalisation, which is crucial for future advanced gate-tunable quantum devices and circuits in tBLG.
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