Metasurface Enhanced Spatial Mode Decomposition
Abstract
Acquiring precise information about the mode content of a laser is critical for multiplexed optical communications, optical imaging with active wave-front control, and quantum-limited interferometric measurements. Hologram-based mode decomposition devices, such as spatial light modulators, allow a fast, direct measurement of the mode content, but they have limited precision due to cross-coupling between modes. Here we report the first proof-of-principle demonstration of mode decomposition with a metasurface, resulting in significantly enhanced precision. A mode-weight fluctuation of was be measured with 1 second of averaging at a Fourier frequency of 80 Hz, an improvement of more than three orders of magnitude compared to the state-of-the-art spatial light modulator decomposition. The improvement is attributable to the reduction in cross-coupling enabled by the exceptional small pixel size of the metasurface. We show a systematic study of the limiting sources of noise, and we show that there is a promising path towards complete mode decomposition with similar precision.
Cite
@article{arxiv.2109.04663,
title = {Metasurface Enhanced Spatial Mode Decomposition},
author = {Aaron W. Jones and Mengyao Wang and Xuecai Zhang and Samuel J. Cooper and Shumei Chen and Conor M. Mow-Lowry and Andreas Freise},
journal= {arXiv preprint arXiv:2109.04663},
year = {2022}
}
Comments
Peer-reviewed version. Accepted for publication in Physical Review A. 6 pages, 8 figures