access icon free Tris-(8-hydroxyquinoline) aluminium thin film as saturable absorber for passively Q-switched erbium-doped fibre laser

© The Institution of Engineering and Technology
Received 14/11/2018, Accepted 12/04/2019, Revised 18/03/2019, Published 13/04/2019

A passively Q-switched erbium-doped fibre laser was demonstrated by using tris-(8-hydroxyquinoline)aluminium (Alq3) organic material as a passive saturable absorber (SA). The SA was fabricated by a drop casting technique at room temperature and incorporated into a laser cavity by inserting it between two optical fibre ferrules. The Q-switched fibre laser operates at a centre wavelength of 1559 nm with a full-width half maximum of 1 nm. The generated pulse train is stable and has a pulse width decreased from 6.65 to 1.2 µs and the pulse repetition rate increased from 31.65 to 144.5 kHz as the pump power increased from 20 to 122 mW. The maximum pulse energy obtained is 63.89 nJ. This work indicates that the Alq3 as SA has a great potential to be utilised for pulsed laser generation. To the best of the authors' knowledge, this is the first time an organic material is utilised as a SA device for generating a stable Q-switched laser pulse.

Inspec keywords: optical pumping; metallic thin films; erbium; casting; laser cavity resonators; optical fibre fabrication; fibre lasers; Q-switching; optical pulse generation; optical saturable absorption; optical films

Other keywords: stable Q-switched laser pulse generation; pulsed laser generation; tris-(8-hydroxyquinoline)aluminium organic material; passive saturable absorber; room temperature; optical fibre ferrules; laser cavity; drop casting technique; temperature 293 K to 298 K; full-width half maximum; passively Q-switched erbium-doped fibre laser; energy 63.89 nJ; wavelength 1559.0 nm; tris-(8-hydroxyquinoline) aluminium thin film; power 20.0 mW to 122.0 mW; wavelength 1.0 nm; time 6.65 mus to 1.2 mus

Subjects: Design of specific laser systems; Laser beam modulation, pulsing and switching; mode locking and tuning; Laser beam modulation, pulsing and switching; mode locking and tuning; Optical materials; Fibre lasers and amplifiers; Optical transient phenomena, self-induced transparency, optical saturation and related effects; Optical materials; Laser resonators and cavities; Laser resonators and cavities; Ultrafast optical techniques; Fibre lasers and amplifiers; Optical fibre fabrication, cladding, splicing, joining; Optical saturation and related effects

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