Journal
IET OPTOELECTRONICS
Volume 14, Issue 5, Pages 278-284Publisher
WILEY
DOI: 10.1049/iet-opt.2019.0153
Keywords
ytterbium; optical pumping; optical saturable absorption; laser cavity resonators; thin films; fibre lasers; Q-switching; tungsten compounds; casting; ytterbium-doped fibre laser cavity; pulse width; pulse laser; passively Q-switched ytterbium laser; tungsten trioxide film absorber; tungsten trioxide-based saturable absorber; Q-switched fibre laser; casting approach; drop approach; powders; polyvinyl alcohol; threshold pump power; repetition rate; pulse energy; signal-to-noise ratio; power 147; 0 mW; energy 625; 0 nJ; frequency 39; 79 kHz; time 2; 37 mus; wavelength 1; 0 mum; wavelength 1063; 78 nm; power 85; 0 mW; frequency 23; 87 kHz; time 5; 56 mus; WO3
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This study experimentally demonstrates a Q-switched fibre laser using a new tungsten tri-oxide (WO3)-based saturable absorber (SA). Using the drop and casting approach, we managed to prepare a thin film that contained WO(3)powders in polyvinyl alcohol. A small bit of the film was used to form an SA which was placed in a ytterbium-doped fibre laser cavity to generate a Q-switched laser. The laser, operating at 1063.78 nm, was realised at the threshold pump power of 85 mW with a repetition rate of 23.87 kHz and a pulse width of 5.56 mu s. At the pump power of 147 mW, the laser produced the maximum pulse energy of 625 nJ, signal-to-noise ratio of 59 dB, the repetition rate of 39.79 kHz and pulse width of 2.37 mu s. To the best of our knowledge, this is the first demonstration of using WO(3)SA to generate the pulse laser in the 1 mu m region.
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