Ring Resonator of Hollow-Core Photonic Crystal Fiber Based on Spatial Coupling Scheme

In this paper, we proposed a hollow-core photonic crystal fiber (HCPCF) ring resonator based on a spatial coupling method, and the component is only 22×30×6mm 3 . When using a 7-core photonic crystal fiber with a mode field diameter of 10um, a ring resonator with the measured finesse of 18 can be bu...

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Veröffentlicht in:	Journal of lightwave technology 2023-08, Vol.41 (16), p.1-7
Hauptverfasser:	Fan, Wen, She, Xuan, Shen, Heliang, Huang, Fei, Bi, Ran, Chen, Kan, Chen, Xingfan, Shu, Xiaowu
Format:	Artikel
Sprache:	eng
Schlagworte:	Couplings Crystal fibers Diameters hollow-core photonic crystal fiber Lenses Optical benches Optical coupling Optical fiber couplers Optical fiber polarization Optical polarization Optical ring resonators Photonic crystals Resonant fiber optical gyro Resonators Silicon spatial coupling
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creator	Fan, Wen She, Xuan Shen, Heliang Huang, Fei Bi, Ran Chen, Kan Chen, Xingfan Shu, Xiaowu
description	In this paper, we proposed a hollow-core photonic crystal fiber (HCPCF) ring resonator based on a spatial coupling method, and the component is only 22×30×6mm 3 . When using a 7-core photonic crystal fiber with a mode field diameter of 10um, a ring resonator with the measured finesse of 18 can be built, indicating that the coupling loss is as low as 0.41dB. Compact and low-loss closed resonator is accomplished using a highly integrated free space silicon optical bench manufactured by deep silicon etching and tiny optical lens package technology, which promotes the practicality of the HCPCF gyro. In addition, two important factors affecting the spatial optical coupling efficiency, the lens type and the fiber mode field size, are investigated in this paper. The obtained results are instructive for all spatial optical coupling systems.
doi_str_mv	10.1109/JLT.2023.3263293
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When using a 7-core photonic crystal fiber with a mode field diameter of 10um, a ring resonator with the measured finesse of 18 can be built, indicating that the coupling loss is as low as 0.41dB. Compact and low-loss closed resonator is accomplished using a highly integrated free space silicon optical bench manufactured by deep silicon etching and tiny optical lens package technology, which promotes the practicality of the HCPCF gyro. In addition, two important factors affecting the spatial optical coupling efficiency, the lens type and the fiber mode field size, are investigated in this paper. 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subjects	Couplings Crystal fibers Diameters hollow-core photonic crystal fiber Lenses Optical benches Optical coupling Optical fiber couplers Optical fiber polarization Optical polarization Optical ring resonators Photonic crystals Resonant fiber optical gyro Resonators Silicon spatial coupling
title	Ring Resonator of Hollow-Core Photonic Crystal Fiber Based on Spatial Coupling Scheme
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