Designing All-Electric Subwavelength Metasources for Near-Field Photonic Routings
Yang Long, Jie Ren, Zhiwei Guo, Haitao Jiang, Yuqian Wang, Yong Sun, Hong Chen
Abstract
The spatially confined evanescent modes in near-field photonics have been proved to be highly desirable in broad practical scenarios ranging from robust information communications to efficient quantum interactions. However, the feasible applications of these photonics modes are limited due to the lack of fundamental understanding and feasible directional coupling approaches at subwavelengths. Here, we propose all-electric near-field metasources in subwavelength scale without mimicking the polarization features or introducing magnetic dipoles. The near-field selective functions of metasources corresponding to time-reversal, parity-time, and parity symmetries of their inner degree of freedom are exemplified in various optical systems. We experimentally demonstrate the efficient near-field photonic routing achieved in waveguides composed of two kinds of single-negative metamaterials. Our work furthers the understanding of optical near-field symmetry and feasible engineering approaches of directional couplings, which would pave the way for promising integrated near-field photonics devices.