扭曲光子异质结构中相互竞争的各向异性导致的质子手性传播

arXiv - PHYS - Mesoscale and Nanoscale Physics Pub Date : 2024-09-17 DOI:arxiv-2409.11066

Ze-Hua Tao, Icaro R. Lavor, Hai-Ming Dong, Andrey Chaves, David Neilson, Milorad V. Milosevic

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引用次数: 0

摘要

我们展示了等离子体极化子的手性传播，并证明它比最近观测到的手性剪切声子极化子更有效、更容易控制。我们考虑了在各向异性二维（2D）材料中产生的等离子体极化子，这种极化子相对于各向异性基底发生扭曲，从而充分利用了各向异性电子-电子相互作用与寄主材料各向异性电子结构之间的竞争。然后利用栅极电压和扭转角度来精确控制手性质子极化子，从而克服了手性声子极化子的现有限制。这些发现为基于质子的高效、可调谐纳米光子学和紧凑型高性能片上光学器件提供了可行的机会。

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Chiral propagation of plasmons due to competing anisotropies in a twisted photonic heterostructure

We demonstrate chiral propagation of plasmon polaritons and show it is more efficient and easier to control than the recently observed chiral shear phonon polaritons. We consider plasmon polaritons created in an anisotropic two-dimensional (2D) material, twisted with respect to an anisotropic substrate, to best exploit the competition between anisotropic electron-electron interactions and the anisotropic electronic structure of the host material. Gate voltage and twist angle are then used for precise control of the chiral plasmon polaritons, overcoming the existing restrictions with chiral phonon polaritons. These findings open up feasible opportunities for efficient and tunable plasmon-based nanophotonics and compact high-performance on-chip optical devices.

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arXiv - PHYS - Mesoscale and Nanoscale Physics

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