# Simultaneous Generation of Arbitrary Assembly of Polarization States   with Geometrical-Scaling-Induced Phase Modulation

**Authors:** Ya-Jun Gao, Xiang Xiong, Zhenghan Wang, Fei Chen, Ru-Wen Peng, and Mu, Wang

arXiv: 1905.07537 · 2020-08-19

## TL;DR

This paper introduces a metasurface design that simultaneously generates multiple polarization states using geometrical-scaling-induced phase modulation, enabling advanced on-chip quantum information processing.

## Contribution

The novel metasurface employs L-shaped resonators with varied geometries to produce multiple polarization states simultaneously, overcoming previous limitations.

## Key findings

- Successfully generates multiple polarization states at once
- Allows precise control of polarization and propagation direction
- Enables encoding and decoding of images with polarization profiles

## Abstract

Manipulating the polarization of light on the microscale or nanoscale is essential for integrated photonics and quantum optical devices. Nowadays, the metasurface allows one to build on-chip devices that efficiently manipulate the polarization states. However, it remains challenging to generate different types of polarization states simultaneously, which is required to encode information for quantum computing and quantum cryptography applications. By introducing geometrical-scaling-induced (GSI) phase modulations, we demonstrate that an assembly of circularly polarized (CP) and linearly polarized (LP) states can be simultaneously generated by a single metasurface made of L-shaped resonators with different geometrical features. Upon illumination, each resonator diffracts the CP state with a certain GSI phase. The interaction of these diffractions leads to the desired output beams, where the polarization state and the propagation direction can be accurately tuned by selecting the geometrical shape, size, and spatial sequence of each resonator in the unit cell. As an example of potential applications, we show that an image can be encoded with different polarization profiles at different diffraction orders and decoded with a polarization analyzer. This approach resolves a challenging problem in integrated optics and is inspiring for on-chip quantum information processing.

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Source: https://tomesphere.com/paper/1905.07537