Arbitrary polarization-independent backscattering or reflection by rotationally symmetric reciprocal structures

arXiv: Optics Pub Date : 2020-11-02 DOI:10.1103/PHYSREVB.103.045422

Weijin Chen, Qingdong Yang, Yuntian Chen, Wei Liu

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引用次数: 1

Abstract

We study the backward scatterings of plane waves by reciprocal scatterers and reveal that $n$-fold ($n\geq3$) rotation symmetry is sufficient to secure invariant backscattering for arbitrarily-polarized incident plane waves. It is further demonstrated that the same principle is also applicable for infinite periodic structures in terms of reflection, which simultaneously guarantees the transmission invariance if there are neither Ohmic losses nor extra diffraction channels. At the presence of losses, extra reflection symmetries (with reflection planes either parallel or perpendicular to the incident direction) can be incorporated to ensure simultaneously the invariance of transmission and absorption. The principles we have revealed are protected by fundamental laws of reciprocity and parity conservation, which are fully independent of the optical or geometric parameters of the photonic structures. The optical invariance obtained is intrinsically robust against perturbations that preserve reciprocity and the geometric symmetries, which could be widely employed for photonic applications that require stable backscatterings or reflections.

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任意偏振无关的后向散射或旋转对称互反结构的反射

我们通过互易散射体研究了平面波的后向散射，并揭示了$n$ -fold ($n\geq3$)旋转对称性足以保证任意极化入射平面波的不变后向散射。进一步证明了同样的原理在反射方面也适用于无限周期结构，在不存在欧姆损耗和额外衍射通道的情况下同时保证了传输不变性。在存在损耗的情况下，可以加入额外的反射对称(与入射方向平行或垂直的反射平面)，以同时确保传输和吸收的不变性。我们所揭示的原理受到互易和宇称守恒基本定律的保护，它们完全独立于光子结构的光学或几何参数。所获得的光学不变性对保持互易性和几何对称性的扰动具有内在的鲁棒性，这可以广泛应用于需要稳定的后向散射或反射的光子应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: Optics

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