石墨烯基异质结构中的栅极可调非对称量子点：纯谷极化和禁锢

C Pub Date : 2024-05-08 DOI:10.3390/c10020044

A. Belayadi, Panagiotis Vasilopoulos

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摘要

我们探索了在石墨烯基异质结构中利用近距离诱导的自旋轨道耦合（SOC）实现依赖于山谷的隧穿和约束的可能性。我们考虑了石墨烯异质结构上的可门调谐非对称量子点（AQDs），它们表现出 C3v 和/或 C6v 对称性。通过采用紧密结合模型，我们明确揭示了 AQDs 中的纯谷禁锢和谷信号，即通过谷局部密度流，导致实际空间中的谷电荷分离。谷准束缚态的束缚对局部诱导的 SOC 和诱导的 AQD 的空间分布很敏感；它对现场无序也很稳健。所采用的实现纯山谷-霍尔电导率和零电荷电流约束的过程有望为山谷电子光学提供更多选择。

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Gate-Tunable Asymmetric Quantum Dots in Graphene-Based Heterostructures: Pure Valley Polarization and Confinement

We explore the possibility of attaining valley-dependent tunnelling and confinement using proximity-induced spin-orbit couplings (SOCs) in graphene-based heterostructures. We consider gate-tunable asymmetric quantum dots (AQDs) on graphene heterostructures and exhibiting a C3v and/or C6v symmetry. By employing a tight-binding model, we explicitly reveal a pure valley confinement and valley signal in AQDs by streaming the valley local density, leading to valley-charge separation in real space. The confinement of the valley quasi-bound states is sensitive to the locally induced SOCs and to the spatial distribution of the induced AQDs; it is also robust against on-site disorder. The adopted process of attaining a pure valley-Hall conductivity and confinement with zero charge currents is expected to provide more options towards valley-dependent electron optics.

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