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Hauptverfasser: Dong, Zhaohui, Chen, Xianfeng, Dutt, Avik, Yuan, Luqi
Format: Preprint
Veröffentlicht: 2023
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2304.11660
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author Dong, Zhaohui
Chen, Xianfeng
Dutt, Avik
Yuan, Luqi
author_facet Dong, Zhaohui
Chen, Xianfeng
Dutt, Avik
Yuan, Luqi
contents The study of dissipative systems has attracted great attention, as dissipation engineering has become an important candidate towards manipulating light in classical and quantum ways. Here,we investigate the behavior of a topological system with purely dissipative couplings in a synthetic time-frequency space. An imaginary bandstructure is shown, where eigen-modes experience different eigen-dissipation rates during the evolution of the system, resulting in mode competition between edge states and bulk modes. We show that distributions associated with edge states can dominate over bulk modes with stable amplification once the pump and saturation mechanisms are taken into consideration, which therefore points to a laser-like behavior for edge states robust against disorders. This work provides a scheme for manipulating multiple degrees of freedom of light by dissipation engineering, and also proposes a great candidate for topological lasers with dissipative photonics.
format Preprint
id arxiv_https___arxiv_org_abs_2304_11660
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Topological Dissipative Photonics and Topological Insulator Lasers in Synthetic Time-Frequency Dimensions
Dong, Zhaohui
Chen, Xianfeng
Dutt, Avik
Yuan, Luqi
Optics
The study of dissipative systems has attracted great attention, as dissipation engineering has become an important candidate towards manipulating light in classical and quantum ways. Here,we investigate the behavior of a topological system with purely dissipative couplings in a synthetic time-frequency space. An imaginary bandstructure is shown, where eigen-modes experience different eigen-dissipation rates during the evolution of the system, resulting in mode competition between edge states and bulk modes. We show that distributions associated with edge states can dominate over bulk modes with stable amplification once the pump and saturation mechanisms are taken into consideration, which therefore points to a laser-like behavior for edge states robust against disorders. This work provides a scheme for manipulating multiple degrees of freedom of light by dissipation engineering, and also proposes a great candidate for topological lasers with dissipative photonics.
title Topological Dissipative Photonics and Topological Insulator Lasers in Synthetic Time-Frequency Dimensions
topic Optics
url https://arxiv.org/abs/2304.11660