Title :
Temporally Stable Random Fiber Laser Operates at 1070 nm
Author :
Xueyuan Du ; Hanwei Zhang ; Hu Xiao ; Pu Zhou ; Zejin Liu
Author_Institution :
Coll. of Optoelectron. Sci. & Eng., Nat. Univ. of Defense Technol., Changsha, China
Abstract :
We experimentally demonstrate a temporally stable random fiber laser (RFL) operating at 1070-nm wavelength. A piece of 25-km passive fiber pumped by a 1018-nm ytterbium-doped fiber laser provides both Raman amplification from stimulated Raman scattering and random distributed feedback via Rayleigh scattering. The laser output of the RFL system shows temporally stable characteristics, despite the high-intensity noise of the pump source. The output power of the 1070-nm RFL reaches the 10-W level. The RFL working in the wavelength range between 1.06 and 1.09 μm is reported for the first time, to the best of our knowledge, in this paper. We believe that our result may be further applied in high-power fiber laser amplifications.
Keywords :
Rayleigh scattering; distributed feedback lasers; fibre lasers; laser stability; laser transitions; optical pumping; random processes; RFL; Raman amplification; Rayleigh scattering; high-intensity noise; passive fiber pumping; pump source; random distributed feedback; stimulated Raman scattering; temporally stable random fiber laser; wavelength 1.06 mum to 1.09 mum; wavelength 1070 nm; ytterbium-doped fiber laser; Distributed feedback devices; Laser excitation; Optical fiber amplifiers; Optical fiber communication; Optical fiber devices; Oscillators; Wavelength division multiplexing; Random fiber laser; Rayleigh scattering; random distributed feedback; random fiber laser; stimulated Raman scattering;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2015.2477279
