Salvato in:
Dettagli Bibliografici
Autori principali: Li, Jing, Lu, Tian-Xiang, Peng, Meiyu, Kuang, Le-Man, Jing, Hui, Zhou, Lan
Natura: Preprint
Pubblicazione: 2024
Soggetti:
Accesso online:https://arxiv.org/abs/2406.18036
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866910502308806656
author Li, Jing
Lu, Tian-Xiang
Peng, Meiyu
Kuang, Le-Man
Jing, Hui
Zhou, Lan
author_facet Li, Jing
Lu, Tian-Xiang
Peng, Meiyu
Kuang, Le-Man
Jing, Hui
Zhou, Lan
contents A circulator is one of the crucial devices in quantum networks and simulations. We propose a four-port circulator that regulate the flow of single photons at muti-frequency points by studying the coherent transmission of a single photon in a coupled system of two resonators and two waveguides. When both resonators are static or rotate at the same angular velocity, single-photon transport demonstrates reciprocity; however, when the angular velocities differ, four distinct frequency points emerge where photon circulation can occur. In particular, when the angular velocities of the two resonators are equal and opposite, there are two different frequency points where photon circulation can be achieved, and there is a frequency point where a single photon input from any waveguide can be completely routed to the other waveguide. Interestingly, by rotating the two resonators, the single-photon circulation suppressed by the internal defect-induced backscattering can be restored.
format Preprint
id arxiv_https___arxiv_org_abs_2406_18036
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Operating Single-Photon Circulator by Spinning Optical Resonators
Li, Jing
Lu, Tian-Xiang
Peng, Meiyu
Kuang, Le-Man
Jing, Hui
Zhou, Lan
Quantum Physics
A circulator is one of the crucial devices in quantum networks and simulations. We propose a four-port circulator that regulate the flow of single photons at muti-frequency points by studying the coherent transmission of a single photon in a coupled system of two resonators and two waveguides. When both resonators are static or rotate at the same angular velocity, single-photon transport demonstrates reciprocity; however, when the angular velocities differ, four distinct frequency points emerge where photon circulation can occur. In particular, when the angular velocities of the two resonators are equal and opposite, there are two different frequency points where photon circulation can be achieved, and there is a frequency point where a single photon input from any waveguide can be completely routed to the other waveguide. Interestingly, by rotating the two resonators, the single-photon circulation suppressed by the internal defect-induced backscattering can be restored.
title Operating Single-Photon Circulator by Spinning Optical Resonators
topic Quantum Physics
url https://arxiv.org/abs/2406.18036