Quantum-coherent optical isolation and circulation using frequency conversion on a chip
Abstract
Breaking optical reciprocity enables new regimes of light--matter interaction with broad implications for fundamental physics and emerging quantum technologies. Although various approaches have been explored to achieve optical nonreciprocity, realizing it at the single-photon level has remained a major challenge. Here, we demonstrate nonmagnetic optical nonreciprocity -- including both isolation and circulation -- in the quantum regime, enabled by efficient and noiseless all-optical frequency conversion on an integrated III-V photonic chip. Our device preserves the quantum coherence and entanglement of the input photons while delivering exceptional performance parameters, including a high extinction ratio of 34 dB, low insertion loss of 0.8 dB, broad bandwidth of 44 GHz, high operational fidelity of 97%, and widely tunable operation wavelength. This realization of quantum optical nonreciprocity in a scalable photonic platform opens a pathway toward directional quantum communication and noise-resilient quantum networks.
Cite
@article{arxiv.2511.00570,
title = {Quantum-coherent optical isolation and circulation using frequency conversion on a chip},
author = {Jierui Hu and Hao Yuan and Joshua Akin and Shanhui Fan and Kejie Fang},
journal= {arXiv preprint arXiv:2511.00570},
year = {2025}
}