Polarization Engineering in Nano-Scale Waveguides Using Lossless Media

TL;DR

This paper introduces nanoscale polarization control devices using lossless media, enabling polarization rotation, splitting, and modulation with high efficiency and bandwidth, overcoming silicon photonics polarization limitations.

Contribution

It proposes novel polarization rotator schemes and a tunable, high-speed, energy-efficient modulator utilizing eigenmode rotation and ENZ effects.

Findings

Achieves polarization rotation with 45° eigenmode rotation in lossless media.

Demonstrates a polarization insensitive modulator with 112 GHz bandwidth.

Provides devices with sub-2 micron length and low energy per bit.

Abstract

A device that achieves controllable rotation of the state of polarization by rotating the orientation of the eigenmodes of a waveguide by 45$^{\circ}$ is introduced and analyzed. The device can be implemented using lossless materials on a nanoscale and helps circumvent the inherent polarization dependence of photonic devices realized within the silicon on insulator platform. We propose and evaluate two novel polarization rotator-based schemes to achieve polarization engineering functions: (1) A multi-purpose device, with dimensions on the order of a few wavelengths which can function as a polarization splitter or an arbitrary linear polarization state generator. (2) An energy efficient optical modulator that utilizes eigenmode rotation and epsilon near zero (ENZ) effects to achieve high extinction ratio, polarization insensitive amplitude modulation without the need to sweep the device geometry to match the TE and TM mode attributes. By using indium tin oxide (ITO) as an example for a tunable material, the proposed modulator provides polarization insensitive operation and can be realized with a modulation bandwidth of 112 GHz, a length of 1800 nm an energy per bit of 7.5 $fJ$ and an optical bandwidth of 210 nm.