实现安全狄拉克费米子传输的石墨烯纳米皱波导

arXiv - PHYS - Other Condensed Matter Pub Date : 2024-07-29 DOI:arxiv-2407.20148

Seunghyun Jun, Myung-Chul Jung, Nojoon Myoung

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引用次数: 0

摘要

石墨烯中的局域态因其潜在应用而在量子形成科学领域备受关注。尽管石墨烯的输运和电子特性优于其他半导体，但由于其无间隙的特性，实现纳米尺度的限制仍然具有挑战性。在本研究中，我们探索了单层石墨烯纳米皱纹的独特输运特性。我们展示了通过沿纳米皱纹交变的伪磁场来创建一维传导通道，从而实现无泄漏的弹道狄拉克费米子输运。此外，我们还将分析扩展到了弯曲的纳米皱纹，展示了除非弯曲角度足够大，否则可以很好地引导狄拉克费米子的传播。我们对石墨烯纳米皱纹波导的展示，为量子信息技术应用引入了一种通过应变工程控制狄拉克费米子传输的新方法。

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Nanowrinkle Waveguide in Graphene for Enabling Secure Dirac Fermion Transport

Localized states in graphene have garnered significant attention in quantum information science due to their potential applications. Despite graphene's superior transport and electronic properties compared to other semiconductors, achieving nanoscale confinement remains challenging due to its gapless nature. In this study, we explore the unique transport properties along nanowrinkles in monolayer graphene. We demonstrate the creation of a one-dimensional conduction channel by alternating pseudo-magnetic fields along the nanowrinkle, enabling ballistic Dirac fermion transport without leakage. This suggests a feasible method for secure quantum information transfer over long distances. Furthermore, we extend our analysis to bent nanowrinkles, showcasing well-guided Dirac fermion propagation unless the bent angle is sufficiently large. Our demonstration of the nanowrinkle waveguide in graphene introduces a novel approach to controlling Dirac fermion transport through strain engineering, for quantum information technology applications.

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arXiv - PHYS - Other Condensed Matter

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