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Quantum Squeezing Induced Optical Nonreciprocity

Quantum Physics 2022-02-25 v1

Abstract

We propose an all-optical approach to achieve optical nonreciprocity on a chip by quantum squeezing one of two coupled resonator modes. By parametric pumping a nonlinear resonator unidirectionally with a classical coherent field, we squeeze the resonator mode in a selective direction due to the phase-matching condition, and induce a chiral photon interaction between two resonators. Based on this chiral interresonator coupling, we achieve an all-optical diode and a three-port quasi-circulator. By applying a second squeezed-vacuum field to the squeezed resonator mode, our nonreciprocal device also works for single-photon pulses. We obtain an isolation ratio of >40 dB for the diode and fidelity of >98%>98\% for the quasi-circulator, and insertion loss of <1 dB for both. We also show that nonreciprocal transmission of strong light can be switched on and off by a relative weak pump light. This achievement implies a nonreciprocal optical transistor. Our protocol opens up a new route to achieve integrable all-optical nonreciprocal devices permitting chip-compatible optical isolation and nonreciporcal quantum information processing.

Keywords

Cite

@article{arxiv.2110.05016,
  title  = {Quantum Squeezing Induced Optical Nonreciprocity},
  author = {Lei Tang and Jiangshan Tang and Mingyuan Chen and Franco Nori and Min Xiao and Keyu Xia},
  journal= {arXiv preprint arXiv:2110.05016},
  year   = {2022}
}
R2 v1 2026-06-24T06:46:54.354Z