Ultralong Single‐Ended Random Fiber Laser and Sensor

Random fiber laser (RFL) utilizing stimulated Raman scattering and distributed random Rayleigh backscattering in fiber as optical gain and feedback mechanisms, respectively, has been developed rapidly in the past decade. Here, it is found, for the first time, that the combination of a high‐order pum...

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Bibliographic Details
Published inLaser & photonics reviews Vol. 17; no. 6
Main Authors Han, Bing, Wu, Han, Liu, Yang, Dong, Shisheng, Rao, Yunjiang, Wang, Zinan, Xu, Jiangming, Ma, Lingmei
Format Journal Article
LanguageEnglish
Published Weinheim Wiley Subscription Services, Inc 01.06.2023
Subjects
Backscattering
Doped fibers
Erbium
fiber Bragg grating
Fiber lasers
Gas pipelines
Lasing
Natural gas
optical fiber sensors
Petroleum pipelines
Power lines
Raman spectra
random fiber lasers
Reflectors
remote sensing
Remote sensors
Sensors
Transmission loss
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Summary:Random fiber laser (RFL) utilizing stimulated Raman scattering and distributed random Rayleigh backscattering in fiber as optical gain and feedback mechanisms, respectively, has been developed rapidly in the past decade. Here, it is found, for the first time, that the combination of a high‐order pump and new transmission fiberthat has lower transmission loss, Rayleigh backscattering coefficient, and Raman gain coefficient than standard single‐mode fibercan break the length limits of both random fiber lasing and sensing. With a higher‐order pump and ultralow loss fiber (ULLF), the position of maximum intracavity lasing power can be shifted toward the far end of the fiber span resulting in more remote pump power for the erbium‐doped fiber (EDF) inserted in the fiber span, which plays a dominant role of cavity length extension in RFL. A 200 km ultralong single‐ended RFL and sensor are experimentally demonstrated, which are the longest single‐ended RFL and sensor with functional remote reflectors reported to date. It is believed that the proposed combination of high‐order random lasing and ULLF with EDF can become a general method to extend the working distance of various fiber sensing systems for safety monitoring of ultralong infrastructures, such as power transmission lines and oil/gas pipelines. A new scheme is proposed to break the length limits of both random fiber lasing and sensing with the combination of high‐order pump and new transmission fiber. A record long (200 km) random fiber laser and sensor are experimentally demonstrated. Such a combination can become a general method to extend the working distances of various fiber sensing systems.
ISSN:1863-8880
1863-8899
DOI:10.1002/lpor.202200797