量子点中自旋轨道耦合诱导的可控量子痕

IF 4.703 3区 材料科学
Lin Zhang, Yutao Hu, Zhao Yao, Xiaochi Liu, Wenchen Luo, Kehui Sun, Tapash Chakraborty
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引用次数: 0

摘要

自旋轨道耦合(SOC)源于狄拉克方程中的相对论修正,在经典极限中具有非线性,能够驱动混沌动力学。在一个由带有 SOC 的二维抛物线势约束的纳米级量子点中,当两个方向的约束能量之比接近可比时,系统的特征态中会准周期性地出现各种量子疤痕态。由于相对论效应,电子密度上的疤痕同时显示出量子干涉和经典轨迹特征,成为系统经典和量子行为之间的桥梁。当拉什巴SOC和德雷斯豪斯SOC的强度相同时,由于经典汉密尔顿方程变得线性,经典极限中的混沌被消除,从而导致所有量子痕态的消失。重要的是,SOC 诱导的量子疤痕对系统参数的微小扰动具有鲁棒性。通过外部门控实现精确控制,拉什巴 SOC 诱导的量子痕是完全可控和可探测的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Controllable quantum scars induced by spin–orbit couplings in quantum dots

Controllable quantum scars induced by spin–orbit couplings in quantum dots

Spin–orbit couplings (SOCs), originating from the relativistic corrections in the Dirac equation, offer nonlinearity in the classical limit and are capable of driving chaotic dynamics. In a nanoscale quantum dot confined by a two-dimensional parabolic potential with SOCs, various quantum scar states emerge quasi-periodically in the eigenstates of the system, when the ratio of confinement energies in the two directions is nearly commensurable. The scars, displaying both quantum interference and classical trajectory features on the electron density, due to relativistic effects, serve as a bridge between the classical and quantum behaviors of the system. When the strengths of Rashba and Dresselhaus SOCs are identical, the chaos in the classical limit is eliminated as the classical Hamilton’s equations become linear, leading to the disappearance of all quantum scar states. Importantly, the quantum scars induced by SOCs are robust against small perturbations of system parameters. With precise control achievable through external gating, the quantum scar induced by Rashba SOC is fully controllable and detectable.

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来源期刊
Nanoscale Research Letters
Nanoscale Research Letters NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
15.00
自引率
0.00%
发文量
110
审稿时长
2.5 months
期刊介绍: Nanoscale Research Letters (NRL) provides an interdisciplinary forum for communication of scientific and technological advances in the creation and use of objects at the nanometer scale. NRL is the first nanotechnology journal from a major publisher to be published with Open Access.
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