Near-Field Optical MIMO Communication with Polarization-dependent Metasurfaces

Abstract: The ability to control waves at the nanoscale has attracted considerable attention to ultrathin metasurface lenses (metalenses) in optical imaging and encryption systems. We propose an approach to active tuning metasurfaces by integrating an ultrathin layer of indium-tin-oxide (ITO) into a unit cell as an electro-optically tunable material. A proposed design features two orthogonal wings that can independently manipulate waves with corresponding orthogonal polarizations. The charge carrier concentration in the ITO accumulation layer is altered by modulating the applied bias voltage. This bias voltage generates phase variations at terahertz frequencies for the reflected transverse electric and transverse magnetic polarized waves. It is possible to move both focal points of a metalens without any physical movement by varying the bias voltage. In addition, this paper explores the application of virtually moving metalens for a novel multiple-input and multiple-output (MIMO) communication architecture. We demonstrate a communication system based on single-point binary data communication and hexadecimal orbital angular momentum (OAM) data communication. Then, orthogonal channels can be used for MIMO communication with high capacity. The proposed design paves the way for high-speed communications as well as polarization-controlled molecular imaging systems.