Liu Guang Yao, Li Long, Han Jia Qi, Liu Hai Xia, Gao Xiao He, Shi Yan, Cui Tie Jun
Key Laboratory of High Speed Circuit Design and EMC of Ministry of Education, School of Electronic Engineering, Xidian University, Xi'an, Shaanxi 710071, China.
State Key Laboratory of Millimeter Waves, Southeast University, Nanjing, Jiangsu 210096, China.
ACS Appl Mater Interfaces. 2020 May 20;12(20):23554-23564. doi: 10.1021/acsami.0c02467. Epub 2020 May 8.
The recently proposed digital reconfigurable metasurfaces make it possible to manipulate electromagnetic (EM) waves flexibly. However, most existing reconfigurable metasurfaces can only exhibit a relatively single performance in the spatial domain. Here, we propose a general frequency- and spatial-domain reconfigurable metasurface (FSRM) that can manipulate the EM waves and realize reconfigurable functions in multifrequency bands. In the frequency domain, FSRM can convert different linearly polarized (LP) incident waves into left- and right-hand circularly polarized reflected waves, in which PIN diodes are used to switch the polarization conversions in different frequency bands. When the polarization direction of the incident LP wave is 45° from the +-axis, the FSRM modulates the incident waves as a 1-bit programmable metasurface in the spatial domain. Two-dimensional beam scanning, vortex beams with orbital angular momentums, and specific beams with desired transmission directions are demonstrated via real-time adjustment of the digital coding state. To validate the modulation methodology, an FSRM prototype is fabricated and measured, which could respond to different functions for different polarization incidences. The measured results agree well with the theoretical analyses. The proposed FSRM will provide new opportunities for smart material designs.
最近提出的数字可重构超表面使得灵活操纵电磁波成为可能。然而,大多数现有的可重构超表面在空间域中只能表现出相对单一的性能。在此,我们提出一种通用的频域和空间域可重构超表面(FSRM),它可以操纵电磁波并在多频段实现可重构功能。在频域中,FSRM可以将不同的线偏振(LP)入射波转换为左旋和右旋圆偏振反射波,其中PIN二极管用于在不同频段切换偏振转换。当入射LP波的偏振方向与±轴成45°时,FSRM在空间域中将入射波调制为1位可编程超表面。通过实时调整数字编码状态,展示了二维波束扫描、具有轨道角动量的涡旋波束以及具有所需传输方向的特定波束。为了验证调制方法,制作并测量了一个FSRM原型,它可以对不同偏振入射响应不同的功能。测量结果与理论分析吻合良好。所提出的FSRM将为智能材料设计提供新的机会。
