天然双曲材料中的亚衍射、体积限制极化子:六方氮化硼(报告记录)

J. Caldwell, A. Kretinin, Yiguo Chen, V. Giannini, M. Fogler, Y. Francescato, C. T. Ellis, J. Tischler, C. Woods, A. Giles, Kenji Watanabe, T. Taniguchi, S. Maier, K. Novoselov
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引用次数: 2

摘要

介质张量的主分量符号相反的强各向异性介质称为双曲介质。这些材料允许高度定向、体积受限的慢光模式在深度亚衍射尺寸尺度上传播,导致独特的纳米光子现象。在光谱范围内实现双曲材料主要是通过使用通常由等离子体金属和介电成分组成的人工结构来实现的。然而,虽然已经进行了原理验证实验,但高等离子体损耗和结构的不均匀性限制了大多数实验室的进展。最近,六方氮化硼(hBN)被确定为一种天然双曲材料(NHM),提供了一种低损耗、均匀的介质,可以在中红外波段工作。我们利用了锥形纳米谐振器周期阵列中hBN的NHM响应来证明“双曲极化”,这是一种深度亚衍射导波,它通过体积而不是在双曲材料表面传播。我们已经确定,极化表现为四个系列的共振在两个不同的光谱带,具有相互排斥的依赖于入射光偏振,模态顺序和纵横比。这些观察结果代表了为中红外到太赫兹纳米光子和超材料设备创建NHM构建模块的首次尝试。本讲座还将讨论这些发展的潜在近期应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Sub-diffractional, volume-confined polaritons in a natural hyperbolic material: hexagonal boron nitride (Presentation Recording)
Strongly anisotropic media where principal components of the dielectric tensor have opposite signs are called hyperbolic. These materials permit highly directional, volume-confined propagation of slow-light modes at deeply sub-diffractional size scales, leading to unique nanophotonic phenomena. The realization of hyperbolic materials within the optical spectral range has been achieved primarily through the use of artificial structures typically composed of plasmonic metals and dielectric constituents. However, while proof-of-principle experiments have been performed, the high plasmonic losses and inhomogeneity of the structures limit most advances to the laboratory. Recently, hexagonal boron nitride (hBN) was identified as a natural hyperbolic material (NHM), offering a low-loss, homogeneous medium that can operate in the mid-infrared. We have exploited the NHM response of hBN within periodic arrays of conical nanoresonators to demonstrate ‘hyperbolic polaritons,’ deeply sub-diffractional guided waves that propagate through the volume rather than on the surface of a hyperbolic material. We have identified that the polaritons are manifested as a four series of resonances in two distinct spectral bands that have mutually exclusive dependencies upon incident light polarization, modal order, and aspect ratio. These observations represent the first foray into creating NHM building blocks for mid-infrared to terahertz nanophotonic and metamaterial devices. This talk will also discuss potential near-term applications stemming from these developments.
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