Wu Xiaohu, McEleney Cameron A, Shi Zhangxing, González-Jiménez Mario, Macêdo Rair
Shandong Institute of Advanced Technology, Jinan 250100, Shandong, China.
James Watt School of Engineering, Electronics and Nanoscale Engineering Division, University of Glasgow, Glasgow G12 8QQ, United Kingdom.
ACS Photonics. 2022 Aug 17;9(8):2774-2782. doi: 10.1021/acsphotonics.2c00551. Epub 2022 Jul 20.
Reflection is one of the most fundamental properties of light propagation. The ability to engineer this property can be a powerful tool when constructing a variety of now ubiquitous optical and electronic devices, including one-way mirrors and antennas. Here, we show from both experimental and theoretical evidence that highly asymmetric reflection can be induced in reciprocal hyperbolic materials. This asymmetry stems from the asymmetric cross-polarization conversion between two linearly polarized waves, an intrinsic and more exotic property of hyperbolic media that is bereft of research. In addition to angle-controllable reflection, our findings suggest that optical devices could utilize the polarization of the incident beam, or even the polarization of the output wave, to engineer functionality; additionally, in hyperbolic slabs or films, the asymmetry can be tailored by controlling the thickness of the material. Such phenomena are key for directional-dependent optical and optoelectronic devices.
反射是光传播最基本的特性之一。在构建各种如今无处不在的光学和电子设备(包括单向镜和天线)时,操控这一特性的能力可以成为一种强大的工具。在此,我们从实验和理论证据两方面表明,在互易双曲材料中可以诱导出高度不对称的反射。这种不对称源于两个线偏振波之间的不对称交叉偏振转换,这是双曲介质一种内在且更为奇特的特性,此前尚未得到研究。除了角度可控的反射外,我们的研究结果表明,光学器件可以利用入射光束的偏振,甚至输出波的偏振来设计功能;此外,在双曲平板或薄膜中,可以通过控制材料的厚度来调整不对称性。此类现象对于依赖方向的光学和光电器件至关重要。